Calculators Created by Urvi Rathod

Vishwakarma Government Engineering College (VGEC), Ahmedabad
https://www.linkedin.com/in/urvi-rathod-a3b634177
1266
Formulas Created
1543
Formulas Verified
241
Across Categories

List of Calculators by Urvi Rathod

Following is a combined list of all the calculators that have been created and verified by Urvi Rathod. Urvi Rathod has created 1266 and verified 1543 calculators across 241 different categories till date.
Verified Number Of Edges
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Verified Number Of Faces
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Verified Number Of Vertices
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22 More 2D Geometry Calculators
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Created A Parameter (Nominal T-method)
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Created B Parameter (Nominal T-method)
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Created C Parameter (Nominal T-method)
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Created D Parameter (Nominal T-method)
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12 More ABCD Parameter Calculators
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Created A Parameter (Nominal pi-method)
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Created B Parameter (Nominal pi-method)
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Created C Parameter (Nominal pi-method)
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Created D Parameter (Nominal pi-method)
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12 More ABCD Parameter Calculators
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Created A Parameter (LTL)
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Created Admittance Using A Parameter (LTL)
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Created Admittance Using B Parameter (LTL)
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Created Admittance Using D Parameter (LTL)
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Created B Parameter (LTL)
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Created C Parameter (LTL)
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Created Characteristic Impedance Using B Parameter (LTL)
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Created Characteristic Impedance Using C Parameter (LTL)
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Created D Parameter (LTL)
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Created Impedance Using A Parameter (LTL)
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Created Impedance Using C Parameter (LTL)
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Created Impedance Using D Parameter (LTL)
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Created Length Using A Parameter (LTL)
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Created Length Using B Parameter (LTL)
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Created Length Using C Parameter (LTL)
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Created Length Using D Parameter (LTL)
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Created Propagation Constant Using A Parameter (LTL)
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Created Propagation Constant Using B Parameter (LTL)
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Created Propagation Constant Using C Parameter (LTL)
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Created Propagation Constant Using D Parameter (LTL)
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Verified Coefficient of Friction When Efficiency of a Trapezoidal Threaded Screw is Given
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Verified Coefficient of Friction When Effort in Lowering a Load is Given
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Verified Coefficient of Friction When Effort is Given
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Verified Coefficient of Friction When Torque Required in Lifting a Load with Acme Tread is Given
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Verified Coefficient of Friction When Torque Required in Lowering a Load is Given
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Verified Efficiency of Acme Threaded Screw
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Verified Effort Required in Lifting a Load with Acme Thread
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Verified Effort Required in Lowering a Load
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Verified Helix Angle When Effort Required in Lifting a Load with Acme Screw Thread is Given
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Verified Helix Angle When Effort Required in Lowering a Load is Given
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Verified Helix Angle When Torque Required in Lifting a Load With Acme Screw Thread is Given
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Verified Helix Angle When Torque Required in Lowering a Load is Given
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Verified Load When Effort Required in Lifting a Load with Acme Screw Thread is Given
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Verified Load When Effort Required in Lowering a Load is Given
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Verified Load When Torque Required in Lifting a Load with Acme Screw Thread is Given
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Verified Load When Torque Required in Lowering a Load is Given
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Verified Mean Diameter of Screw When Torque Required in Lowering a Load is Given
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Verified Torque Required in Lifting a Load With Acme Screw Thread
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Verified Torque Required in Lowering a Load
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Created Open-Circuit voltage gain of an amplifier
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Created Open-Circuit voltage gain of an amplifier when short-circuit transconductance is given
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Verified Process transconductance parameter of PMOS
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Verified Transfer Function (for physical frequencies) of STC networks for high pass filter
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38 More Amplifiers Calculators
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Verified Input resistance of the base of the emitter-follower
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Verified Input resistance of the emitter-follower
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Verified Input voltage of the emitter-follower
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Verified Output resistance of the emitter-follower
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Verified Output voltage of the emitter-follower
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Verified Overall voltage gain of the emitter-follower
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Verified Antenna Gain
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Verified Avg Radiation Intensity
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Verified Beam Width
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Verified Directivity Of Antenna
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Verified Isotropic Radiation Intensity
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Verified Max Radiation Intensity
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28 More Antenna & Wave Propogation Calculators
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Created Area Of Core When EMF Induced In Primary Winding Is Given
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Created Area Of Core When EMF Induced In Secondary Winding Is Given
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Created Length Of Line Using Area Of X-section(Two-Wire One Conductor Earthed)
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Created Line Losses Using Area Of X-section(Two-Wire One Conductor Earthed)
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Created Maximum Voltage Using Area Of X-section(DC Two-Wire OS)
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Created Resistivity Using Area Of X-section(Two-Wire One Conductor Earthed)
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Created Transmitted Power Using Area Of X-section(Two-Wire One Conductor Earthed)
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Created Length Using Area Of X-section(DC 3-wire)
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Created Line Losses Using Area Of X-section(DC 3-wire)
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Created Load Current Using Area Of X-section(DC 3-wire)
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Created Maximum Voltage Using Area Of X-section(DC 3-wire)
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Created Power Transmitted Using Area Of X-section(DC 3-wire)
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Created Resistivity Using Area Of X-section(DC 3-wire)
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Created Volume Of Conductor Material Using Area Of X-section(DC 3-wire)
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Created Length Of Wire Using Area Of X-section(1-phase 3-wire OS)
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Created Line Losses Using Area Of X-section(1-phase 3-wire OS)
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Created Load Current Using Area Of X-section(1-Phase 3-Wire OS)
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Created Maximum Voltage Using Area Of X-section(1-phase 3-wire OS)
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Created Power Factor Using Area Of X-section(1-phase 3-wire OS)
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Created Power Transmitted Using Area Of X-section(1-phase 3-wire OS)
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Created Resistivity Using Area Of X-section(1-phase 3-wire OS)
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Created RMS Voltage Using Area Of X-Section(1-Phase 3-Wire OS)
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Created Length Of Wire Using Area Of X-section(1-phase 2-wire OS)
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Created Line Losses Using Area Of X-section(1-phase 2-wire OS)
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Created Load Current Using Area Of X-Section(1-Phase 2-Wire OS)
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Created Maximum Voltage Using Area Of X-section(1-phase 2-wire OS)
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Created Power Factor Using Area Of X-section(1-phase 2-wire OS)
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Created Power Transmitted Using Area Of X-section(1-phase 2-wire OS)
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Created Resistivity Using Area Of X-section(1-phase 2-wire OS)
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Created RMS Voltage Using Area Of X-Section(1-Phase 2-Wire OS)
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Created Length Of Wire Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Created Line Losses Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Created Load Current Using Area Of X-Section(1-Phase 2-Wire Mid-point Earthed OS)
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Created Maximum Voltage Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Created Power Factor Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Created Power Transmitted Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Created Resistivity Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Created RMS Voltage Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Created Volume Of Conductor Material Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Created Angle Of PF Using Area Of X-section(3-phase 4-wire OS)
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Created Length Of Wire Using Area Of X-section(3-phase 4-wire OS)
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Created Line Losses Using Area Of X-section(3-phase 4-wire OS)
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Created Maximum Voltage Using Area Of X-section(3-phase 4-wire OS)
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Created Power Factor Using Area Of X-section(3-phase 4-wire OS)
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Created Power Transmitted Using Area Of X-section(3-phase 4-wire OS)
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Created Resistivity Using Area Of X-section(3-phase 4-wire OS)
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Created RMS Voltage Using Area Of X-section(3-phase 4-wire OS)
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Created Angle Of PF Using Area Of X-section(3-phase 3-wire OS)
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Created Length Of Wire Using Area Of X-section(3-phase 3-wire OS)
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Created Line Losses Using Area Of X-section(3-phase 3-wire OS)
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Created Maximum Voltage Using Area Of X-section(3-phase 3-wire OS)
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Created Power Factor Using Area Of X-section(3-phase 3-wire OS)
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Created Power Transmitted Using Area Of X-section(3-phase 3-wire OS)
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Created Resistivity Using Area Of X-section(3-phase 3-wire OS)
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Created RMS Voltage Using Area Of X-section(3-phase 3-wire OS)
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Created Length Of Wire Using Area Of X-section(2-phase 3-wire OS)
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Created Line Losses Using Area Of X-Section(2-phase 3-wire OS)
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Created Load Current Using Area Of X-Section(2-phase 3-wire OS)
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Created Maximum Voltage Using Area Of X-Section(2-phase 3-wire OS)
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Created Power Factor Using Area Of X-section(2-phase 3-wire OS)
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Created Power Transmitted Using Area Of X-Section(2-phase 3-wire OS)
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Created Resistivity Using Area Of X-Section(2-phase 3-wire OS)
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Created RMS Voltage Using Area Of X-Section(2-phase 3-wire OS)
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Created Volume Of Conductor Material Using Area Of X-Section(2-phase 3-wire OS)
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Created Length Of Wire Using Area Of X-section(2-phase 4-wire OS)
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Created Line Losses Using Area Of X-Section(2-phase 4-wire OS)
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Created Load Current Using Area Of X-section(2-phase 4-wire OS)
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Created Maximum Voltage Using Area Of X-section(2-phase 4-wire OS)
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Created Power Factor Using Area Of X-section(2-phase 4-wire OS)
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Created Power Transmitted Using Area Of X-Section(2-phase 4-wire OS)
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Created Resistivity Using Area Of X-Section(2-phase 4-wire OS)
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Created RMS Voltage Using Area Of X-Section(2-phase 4-wire OS)
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Created Volume Of Conductor Material Using Area Of X-Section(2-phase 4-wire OS)
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Created Constant Using Area Of X-Section (1-Phase 2-Wire US)
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Created Length Using Area Of X-Section (1-Phase 2-Wire US)
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Created Line Losses Using Area Of X-Section (1-Phase 2-Wire US)
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Created Maximum Voltage Using Area Of X-Section (1-Phase 2-Wire US)
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Created Power Factor Using Area Of X-Section (1-Phase 2-Wire US)
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Created Power Transmitted Using Area Of X-Section (1-Phase 2-Wire US)
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Created Resistivity Using Area Of X-Section (1-Phase 2-Wire US)
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Created RMS Voltage Using Area Of X-Section (1-Phase 2-Wire US)
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Created Volume Of Conductor Material Using Area Of X-Section (1-Phase 2-Wire US)
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Verified Diameter of the Shaft When Principle Shear Stress is Given
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Verified Equivalent Bending Moment When Shaft is Subjected to Fluctuating Loads
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Verified Equivalent Torsional Moment When Shaft is Subjected to Fluctuating Loads
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Verified Principle Shear Stress(maximum shear stress theory of failure)
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Verified Input resistance of the amplifier
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Verified Overall voltage gain when load resistance is connected at the amplifier
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Created Small signal input resistance in terms of common base current gain
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Verified Small signal input voltage in terms of the transconductance
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Verified Small signal voltage in terms of resistance
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Verified Voltage between gate and source
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Verified Voltage gain from base to collector
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Verified Voltage gain from base to collector in terms of transconductance
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Verified Voltage gain in terms of common base current gain
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Verified Voltage gain in terms of load resistance
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Verified Voltage gain in terms of load resistance of BJT
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Verified Voltage gain in terms of load resistance of the MOSFET
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Verified Voltage gain when load resistance is connected at the amplifier
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Verified Voltage gain when load resistance of MOSFET and transconductance are given
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12 More Basic Configurations Calculators
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Verified Capacitance of the varactor diode
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Verified Conductivity in metals
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Verified Conductivity in semiconductors
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Verified Conductivity of extrinsic semiconductor for p-type
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Verified Conductivity of extrinsic semiconductors for n-type
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Verified Current in Zener diode(Zener current)
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Verified Cut-off frequency of varactor diode
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Verified Diode Equation
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Verified Einstein's Equation
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Verified Electron diffusion length
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Verified Electrostatic deflection sensitivity
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Verified Ideal Diode Equation
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Verified Intrinsic concentration
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Verified Magnetic deflection sensitivity
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Verified Majority carrier concentration
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Verified Mobility of a charge carriers
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Verified Non-Ideal Diode Equation
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Verified Quality factor of the varactor diode
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Verified Self-resonance of the varactor diode
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Verified Thermal Voltage
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Verified Thermal voltage of Diode equation
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Verified Velocity due to voltage
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1 More Basic Electronics Calculators
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Verified Intrinsic gain of the BJT
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Verified Output resistance of the transistor at an intrinsic gain
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Verified Transconductance of the BJT at an intrinsic gain
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Verified Voltage gain of amplifier with current-source load in terms of finite output resistance
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Verified Voltage gain of the amplifier with the current-source load
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6 More Basic gain cell in an IC amplifier Calculators
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Verified DC Bias Voltage
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Verified Drain current in the load line
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Verified Maximum voltage gain at the bias point
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Verified Maximum voltage gain when all voltages are given
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Verified Overdrive voltage when MOSFET acts as an amplifier in terms of load resistance
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Verified Voltage across collector-emitter of BJT Amplifier
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Verified Voltage gain at bias point in terms of overdrive voltage
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Verified Voltage gain at the bias point
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Verified Voltage gain in terms of drain current
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Verified Voltage gain in terms of drain voltage
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Verified Voltage gain when all voltages are given
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Verified voltage gain when the collector current is given
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10 More Basic Principles Calculators
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Verified Battery Life
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Verified Braking Torque When Brakes are Applied
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Verified Coefficient of Friction When Braking Torque is Given
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Verified Normal Reaction Force
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Verified Normal Reaction Force When Braking Torque is Given
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Verified Permissible Pressure Between the Block and Brake Drum When Normal Reaction is Given
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Verified Radius of the Drum Brake When Braking Torque is Given
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2 More Block Brake With Short Shoe Calculators
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Verified Angular Momentum
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Verified Bohr's Radius
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Verified Change In Wave Number Of A Moving Particle
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Verified Change In Wavelength Of A Moving Particle
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Verified Frequency Using Energy
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Verified Kinetic Energy Of A Electron
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Verified Potential Energy Of Electron
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Verified Radius Of The Orbit
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Verified Total Energy Of Electron
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Verified Velocity Of The Particle
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Verified Wave Number Of A Moving Particle
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Verified Wavelength Of A Moving Particle
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Verified Wavelength Using Energy
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22 More Bohr's atomic model Calculators
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Verified Core Diameter of Bolt When Maximum Tensile Stress in the Bolt is Given
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Verified Core Diameter When Strength of Bolt in Tension is Given
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Verified Factor of Safety When Strength of Bolt in Tension is Given
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Verified Maximum Tensile Stress in the Bolt
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Verified Strength of Bolt in Tension
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Verified Tensile Force When Maximum Tensile Stress in the Bolt is Given
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Verified Yield Strength in Tension When Strength of Bolt in Tension is Given
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10 More Bolted Joints Calculators
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Verified Current transfer ratio of IC Amplifier in terms of β
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Verified Finite input resistance of small-signal operation of current mirrors in terms of transconductance
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Verified Output current of IC amplifier in terms of β
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Verified Output current of the IC amplifier
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Verified Output current of the IC Amplifier
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Verified Output resistance in small-signal operation of current mirrors
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Verified Reference current of BJT Mirror
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Verified Reference current of BJT Mirror in terms of the collector current
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Verified Reference current of the IC amplifier
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17 More Building Blocks of Integrated-Circuit Amplifiers Calculators
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Verified Capacitance for Parallel Plate Capacitors with Dielectric Between Them
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Verified Capacitor with dielectric
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Verified Energy Density in Electric Field when Free Space Permittivity is Given
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Verified Energy Density when an electric field is given
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15 More Capacitor Calculators
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Verified Cross-sectional Area of Rod When Strain Energy stored in a Rod is Given
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Verified Force Applied on the Rod When Strain Energy Stored in Tension Rod is Given
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Verified Length of Shaft When Strain Energy in the Shaft Subjected to External Torque
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Verified Length of the Rod When Strain Energy Stored is Given
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Verified Length of the Shaft When Strain Energy Stored in the Shaft Subjected to Bending Moment is Given
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Verified Modulus of Elasticity of the Rod When Strain Energy Stored is Given
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Verified Modulus of Elasticity When Strain Energy Stored in the Shaft Subjected to Bending Moment is Given
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Verified Modulus of Rigidity of the Rod When Strain Energy in the Rod is Given
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Verified Moment of Inertia of Shaft When Strain Energy Stored in Shaft Subjected to Bending Moment
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Verified Polar Moment of Inertia of the Rod When Strain Energy in the Rod is Given
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Verified Strain Energy in the Rod When it is Subjected to External Torque
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Verified Strain Energy Stored in Tension Rod
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Verified Strain Energy Stored in the Rod Subjected to Bending Moment
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Verified Torque When Strain Energy in the Rod When Subjected to External Torque is Given
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Verified Acceptable MTBF
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Verified Activity factor
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Verified Adjacent capacitance
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Verified Agression Driver
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Verified Agression Time Constant
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Verified Agressor Voltage
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Verified Aperture times for falling inputs
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Verified Aperture times for rising
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Verified Area of a memory cell
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Verified Area of a memory containing N bits
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Verified Area Of Source Diffusion(AS)
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Verified Array efficiency
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Verified Bit Capacitance
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Verified Body effect coefficient
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Verified Branching effort
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Verified Built-in potential
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Verified Capacitance gate to base
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Verified Capacitance gate to drain
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Verified Capacitance gate to source
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Verified Capacitance Gnd-V
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Verified capacitance junction between body and bottom of source
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Verified Capacitance Of Gate Oxide
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Verified Capacitance of junction between body and sidewalls of source
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Verified capacitance of the external load
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Verified Capacitance Offpath
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Verified Capacitance Onpath
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Verified Capacitor dynamic power
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Verified Carry-Increamentor Adder Delay
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Verified Carry-Looker Adder (CLA) delay
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Verified Carry-Ripple adder critical path delay
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Verified Carry-Skip Adder Delay
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Verified Cell Capacitance
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Verified Change in Frequency of Clock
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Verified Change in Phase of Clock
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Verified Channel Charge
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Verified CMOS Dynamic Power
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Verified CMOS Saturation Voltage
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Verified CMOS Short-Circuit Power
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Verified CMOS Static Power
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Verified CMOS Total Power
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Verified Contention current in ratioed circuits
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Verified Critical Electric Field CMOS
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Verified Critical Path Delay
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Verified Critical Voltage
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Verified Delay Fall
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Verified Delay of Chains
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Verified Delay of the 1-bit propagate/generate gates
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Verified Delay of the AND-OR gate in the gray cell
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Verified Delay Previous
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Verified Delay rise
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Verified Depletion region Width
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Verified DIBL coefficient
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Verified Drain Voltage
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Verified Drive of an arbitrary gate
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Verified Duty Cycle Time in CMOS
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Verified Edge rate
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Verified Effective Capacitance in CMOS
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Verified Effective Channel Length
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Verified Energy Delay Product
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Verified fall resistance
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Verified Fall time
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Verified fanout of the gate
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Verified Feedback Clock PLL
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Verified Gate Capacitance
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Verified Gate Delay
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Verified Gate leakage through gate dielectric
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Verified Gate Length
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Verified Gate to Channel Voltage
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Verified Gates On Critical Path
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Verified Ground to Agression capacitance
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Verified Group Propagation delay
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Verified HIGH Noise Margin
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Verified Hold Time at High logic
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Verified Hold Time at Low logic
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Verified Initial Voltage of Node A
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Verified Input capacitance of the gate
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Verified Input Clock Phase PLL
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Verified Intrinsic Fall
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Verified Intrinsic gate capacitance
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Verified Intrinsic Rise
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Verified Invertor Electric Effort 1
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Verified Invertor Electric Effort 2
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Verified Invertor Power
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Verified Junction Current
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Verified K-input AND gate
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Verified K-Prime
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Verified Leakage Energy in CMOS
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Verified Length of Source(D)
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Verified Lock Voltage
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Verified Logical effort(g)
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Verified LOW Noise margin
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Verified Maximum allowable power supply ripple
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Verified Maximum LOW input voltage
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Verified Maximum LOW output voltage
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Verified Metastable voltage
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Verified Minimum HIGH input voltage
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Verified Minimum HIGH output voltage
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Verified Mobility in Mosfet
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Verified Multiplexer Delay
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Verified N-bit carry-skip adder
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Verified N-Bit SRAM
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Verified n-input AND gate
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Verified Normalized delay
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Verified OFF Current
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Verified Output Clock Phase
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Verified Output Clock Phase PLL
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Verified Oxide Thickness
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Verified Parasitic capacitance
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Verified Permittivity of Oxide Layer
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Verified PLL Phase Detector Error
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Verified Potential difference Source To Body(Vsb)
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Verified Potential from drain to source
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Verified Potential gate to Collector
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Verified Potential Gate to Drain
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Verified Power Consumption of the chip
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Verified Probability of synchronizer failure
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Verified Propagation delay
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Verified Rise Resistance
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Verified Rise time
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Verified Series resistance from the die to the package
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Verified Series resistance from the package to the air
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Verified Setup Time at high Logic
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Verified Setup Time at Low Logic
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Verified Sidewall Perimeter Of Source Diffusion
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Verified slope fall
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Verified Slope Rise
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Verified Small Deviation Delay
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Verified Small signal offset
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Verified Stage effort
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Verified Static Current
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Verified Static Power Dissipation
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Verified Subthreshold leakage through OFF transistors
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Verified Subthreshold slope
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Verified Supply Impedance
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Verified Surface potential
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Verified Switching Energy in CMOS
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Verified Switching Power
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Verified Temperature Difference between Transistors
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Verified Thermal Resistance between junction and Ambient
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Verified Threshold Voltage
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Verified Threshold Voltage of MOSFET
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Verified Threshold Voltage When Source is at body potential
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Verified Time Constant ratio Of Agression to Victim
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Verified Total capacitance seen by a stage
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Verified Total Energy in CMOS
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Verified Total Source Parasitic Capacitance
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Verified Transfer Function of PLL
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Verified Tree Adder Delay
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Verified VCDL gain
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Verified VCO Control Voltage
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Verified VCO Offset Voltage
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Verified VCO Single Gain Factor
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Verified Victim Driver
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Verified Victim Time Constant
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Verified Victim Voltage
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Verified Voltage at Which EDP is minimize
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Verified Voltage Swing On Bitline
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Verified Voltage-Controlled delay line
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Verified Width Of Gate
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Verified Width Of Source Diffusion
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Verified XOR Delay
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Verified XOR Phase Detector average Voltage
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Verified XOR Phase Detector Current
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Verified XOR Phase Detector Phase
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Verified XOR Phase Detector Voltage
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Verified x-Voltage Nand Gate
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Verified Emitter current of the common-base amplifier
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Verified Input resistance of the common-base amplifier
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Verified Input resistance of the common-base amplifier in terms of emitter resistance
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Verified Input voltage of the common-base amplifier
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Verified Output voltage of the common-base amplifier
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Verified Overall voltage gain of the common-base amplifier
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Verified Overall voltage gain of the common-base amplifier in terms of transconductance
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Verified Input resistance of common emitter amplifier in terms of small-signal input resistance
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Verified Input resistance of common-emitter amplifier in terms of emitter resistance
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Verified Input resistance of the common emitter amplifier
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Verified Output resistance of the common-emitter amplifier
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Verified Overall voltage gain of common-emitter amplifier in terms of emitter resistance
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Verified Overall voltage gain of the common-emitter amplifier
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Verified Input resistance of the amplifier
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Verified Input resistance of the common-collector amplifier
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Verified Open-circuit voltage gain of the CS amplifier
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Verified Output resistance of the buffer amplifier
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Verified Output resistance of the common-drain amplifier
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Verified Output resistance of the Emitter-Follower Output
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Verified Overall voltage gain of the amplifier
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Verified Overall voltage gain of the amplifier when load resistance is connected to the output
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Verified Overall voltage gain of the buffer amplifier when the load resistance is given
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Verified Overall voltage gain of the common-collector amplifier
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Verified Overall voltage gain of the source follower
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Verified Voltage gain of the buffer amplifier
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Verified Voltage gain of the common-drain amplifier
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Verified Voltage gain of the CS amplifier
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1 More Common-Gate (CG) and the Common-Base (CB) Amplifiers Calculators
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Verified Overall voltage gain of the common-source amplifier
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2 More Common-source amplifier Calculators
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Verified Hardness Of Water
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Verified Molaity Using Mole Fraction
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Verified Molality Using Molarity
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Verified Molarity
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Verified Molarity Using Molality
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Verified Molarity Using Mole Fraction
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Verified Mole Fraction OF The Solute
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Verified Mole Fraction Of The Solvent
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Verified Mole Fraction Using Molality
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Verified Mole Fraction Using Molarity
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Verified Number Of Moles Of The Solute Using Molarity
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Verified Percentage Of Chlorine In Bleaching Powder
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Verified Relative Atomic Mass
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16 More Concentration terms Calculators
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Verified Axial Force Transmitted by the outer Spring
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Verified Cross-Sectional Area of Inner Spring When Axial Force Transmitted is Given
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Verified Cross-sectional Area of Outer Spring When Axial Force Transmitted is Given
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Verified Cross-sectional Area of the Inner Spring Wire
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Verified Cross-sectional Area of the Outer Spring Wire
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Verified Diametrical Clearance Between the Springs
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Verified Wire Diameter of the Inner Spring When Axial Force Transmitted by the Outer Spring is Given
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Verified Wire Diameter of the Inner Spring When Diametrical Clearance Between the Springs is Given
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Verified Wire Diameter of the Outer Spring When Axial Force Transmitted by the Outer Spring is Given
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Verified Wire Diameter of the Outer Spring When Diametrical Clearance Between the Springs is Given
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1 More Concentric Springs Calculators
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Verified Duty Cycle For Buck Regulator (CCM)
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Verified Input Voltage For Buck Regulator (CCM)
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Verified Output Voltage For Buck Regulator (CCM)
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Verified Duty Cycle For Boost Regulator (CCM)
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Verified Input Voltage For Boost Regulator (CCM)
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Verified Output Voltage For Boost Regulator (CCM)
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Verified Duty Cycle For Buck-Boost Regulator (CCM)
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Verified Input Voltage For Buck-Boost Regulator (CCM)
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Verified Output Voltage For Buck-Boost Regulator (CCM)
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Verified Duty Cycle For Cuk Regulator
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Verified Input Voltage For Cuk Regulator
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Verified Output Voltage For Cuk Regulator
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Created Armature Current Of Series DC Generator Using Converted Power
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Created Armature Current Of Series DC Generator Using Generated Power
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Created Armature Current Of Series DC Generator Using Kf
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Created Armature Current Of Series DC Generator Using Output Power
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Created Armature Current Of Series DC Generator Using Terminal Voltage
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Created Armature Current Of Series DC Generator Using Torque
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Created Load Current Of Series DC Generator Using Output Power
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Verified Collector current when early voltage is given for NPN transistor
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Verified Collector current when early voltage is given for PNP transistor
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Verified Output resistance of BJT
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Verified Output resistance of transistor when base current is constant
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Verified Drift Speed
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Verified Drift Speed when Cross-Sectional Area is Given
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Verified Resistance of a Wire
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Verified Temperature Dependence of Resistance
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23 More Current Electricity Calculators
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Verified Base Current 1 of BJT
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Verified Base Current 2 of BJT
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Verified Collector Current of BJT
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Verified Collector current when emitter current is given
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Verified Collector current when saturation current of DC is given
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Verified Common-base current gain
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Verified Common-emitter current gain in terms of common-base current gain
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Verified Concentration of electrons injected from emitter to base
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Verified Emitter Current
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Verified Emitter current when common-emitter current gain is given
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Verified Emitter current when constant of the transistor is given
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Verified Emitter current when saturation current is given
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Verified Total base current
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Verified Output current of the Widlar Current Source
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Verified Output resistance of the Wilson MOS Mirror
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Verified Reference current of Wilson current mirror
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5 More Current-Mirror Circuits with Improved Performance Calculators
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Verified Amplitude Of Reference signal
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Verified Amplitude Of The Signal Received From Target at Range Ro
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Verified CFA D.C Power Input
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Verified CFA RF drive power
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Verified CW oscillator voltage
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Verified Distance from antenna 1 to the target
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Verified Distance from antenna 2
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Verified Doppler Frequency Shift
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Verified Echo Signal Voltage
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Verified Efficiency Of Cross-Field Amplifier(CFA)
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Verified Measured position at the nth scan
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Verified Peak quantization lobe
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Verified Phase difference between the echo signals
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Verified Position Smoothing parameter
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Verified Predicted position of the target
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Verified Radar antenna height
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Verified Range-resolution
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Verified RF Power output
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Verified Smoothed position
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Verified Smoothed Velocity
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Verified Target height
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Verified Target Velocity
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Verified Time Between Observations
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Verified Velocity Smoothing Parameter
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Created Angular Speed Of The Dc Machine
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Created Armature Current
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Created Back EMF
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Verified Back pitch
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Verified Coil Span
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Created Constant Of The DC Machine
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Created EMF For DC Generator
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Created EMF For DC Generator For Wave Winding
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Created EMF Generated Per Path For A Lap-winding
Go
Created EMF Of Dc Machine When Constant Of The DC Machine Is Given
Go
Created Field Current
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Created Power Generated When The Armature Current Is Given
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Created Power Generated When Torque is Given
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Created Series Generator Terminal Voltage
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Created Shunt Field Current
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Created Shunt Generator Terminal Voltage
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Verified Total power dissipated in MOSFET
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5 More Dc Machine Calculators
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Created Armature Copper Loss
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Created Converted Power
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Created Field Cu Losses
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Created Frequency When Speed Is Given
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Created Input Power 3-Phase
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Created Input Power Per Phase
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Created Mechanical Power In Rotor
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Created Mechanical Power Of When Input Power Is Given
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Created Output Power
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Created Power Loss Due To Brush Drop
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Created Series Field Copper Loss
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Created Shunt Field Copper Loss
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8 More DC Motor Calculators
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Verified Input Offset Voltage of the BJT Differential Amplifier in terms of collector resistance
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Verified Input Offset Voltage of the MOS Differential Amplifier in terms of saturation current
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Verified Total Input Offset Voltage of the MOS Differential Amplifier
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9 More DC Offset Calculators
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Verified De-Brogile Wavelength
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12 More de-Broglie hypothesis Calculators
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Created Delta Impedance For Delta Connected Load Using Negative Sequence Current
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Created Delta Impedance For Delta Connected Load Using Positive Sequence Current
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Created Delta Impedance For Delta Connected Load Using Positive Sequence Voltage
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Created Delta Impedance Using Star Impedance
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Verified Mass Of The Gas Using Vapour Density
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Verified Vapour Density of The Gas Using Mass
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15 More Density for gases Calculators
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Verified Axial Force When Tensile Stress in the Shaft is Given
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Verified Bending Moment When Bending Stress is Given(Pure Bending)
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Verified Bending Stress in the Shaft (Pure Bending Moment)
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Verified Diameter of Shaft When Tensile Stress in the Shaft is Given
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Verified Diameter of Shaft When Torsional Shear Stress in a Shaft is Given(Pure Torsion)
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Verified Diameter of the Shaft When Bending Stress is Given(Pure Bending)
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Verified Normal Stress When Both Bending and Torsional act on the Shaft
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Verified Tensile Stress in the Shaft When It is Subjected to Axial Tensile Force
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Verified Tensile Stress When Normal Stress is Given
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Verified Torsional Moment When Torsional Shear Stress in a Shaft is Given(Pure Torsion)
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Verified Torsional Shear Stress in a Shaft(Pure Torsion)
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4 More Desgin of Shafts Calculators
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Verified Diameter of the Spring Wire When Mean Stress on the Spring is Given
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Verified Diameter of the Spring Wire When Torsional Stress Amplitude is Given
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Verified Force Amplitude of the Spring
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Verified Force Amplitude When Torsional Stress Amplitude is Given
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Verified Maximum Force on the Spring When Mean Force is Given
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Verified Maximum Force When Force Amplitude is Given
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Verified Mean Coil Diameter When Torsional Stress Amplitude is Given
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Verified Mean Diameter of the Coil When Mean Stress on the Spring is Given
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Verified Mean Force
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Verified Mean Force When Mean Stress on the Spring is Given
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Verified Mean Stress on the Spring
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Verified Minimum Force on the Spring When Force Amplitude is Given
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Verified Minimum Force on the Spring When Mean Force is Given
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Verified Shear Stress Correction Factor When Mean Stress on the Spring is Given
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Verified Shear Yield Strength (Oil-hardened Tempered Steel Wires)
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Verified Shear Yield Strength (Patented and Cold-drawn Steel Wires)
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Verified Spring Index When Mean Stress on the spring is Given
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Verified Spring Index When Torsional Stress Amplitude is Given
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Verified Stress Factor When Torsional Stress Amplitude is Given
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Verified Torsional Stress Amplitude
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Verified Ultimate Tensile Stress When Shear Yield Strength is Given (Patented and Cold-drawn Steel Wires)
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Verified Ultimate Tensile Stress When Shear Yield Strength is Given(Oil-hardened Tempered Steel Wires)
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Verified Brake Drum Rotational Angle When Work Done by the Brake is Given
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Verified Braking Torque When Work Done by the Brake is Given
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Verified Final Velocity When Kinetic Energy Absorbed by the Brakes is Given
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Verified Initial Angular Velocity of the Body When Kinetic Energy of the Rotating Body is Given
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Verified Initial Velocity of the System When Kinetic Energy Absorbed by the Brakes is Given
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Verified Kinetic Energy Absorbed by the Brake
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Verified Kinetic energy of a Rotating Body
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Verified Mass of the System When Kinetic Energy Absorbed by the Brakes is Given
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Verified Mass of the System When Kinetic Energy of Rotating Body is Given
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Verified Mass of the System When Potential Energy Absorbed During Braking Period is Given
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Verified Moment of Inertia of the System When Kinetic Energy of the Rotating Body is Given
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Verified Potential Energy Absorbed During Braking Period
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Verified Total Energy Absorbed by the Brake
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2 More Design of Brakes Calculators
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Verified Angle of Twist of Hollow Shaft on Basis oF Torsional Rigidity
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Verified Axial Tensile Force When Tensile Stress in the Hollow Shaft is Given
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Verified Inner Diameter of Hollow Shaft When Ratio of Diameters is Given
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Verified Length of the Shaft When Angle of Twist of Hollow shaft on Basis of Torsional Rigidity is Given
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Verified Modulus of Rigidity When Angle of Twist of Hollow Shaft on basis of Torsional Rigidity
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Verified Outer Diameter of Hollow Shaft When Angle of Twist is Given(Torsional Rigidity)
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Verified Outer Diameter of the Hollow Shaft When Principle Stress is Given
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Verified Outer Diameter of the Shaft When Torsional Shear Stress is Given
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Verified Outer Diameter When Ratio of Diameters is Given
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Verified Principle Stress (Maximum Principle Stress Theory)
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Verified Ratio of Diameters When Angle of Twist of Hollow Shaft (Torsional Rigidity) is Given
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Verified Ratio of Diameters When Bending Stress of Hollow Shaft is Given
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Verified Ratio of Diameters When Principle Stress is Given
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Verified Ratio of Diameters When Tensile Stress in Hollow Shaft is Given
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Verified Ratio of Diameters When Torsional Shear Stress in a Hollow Shaft is Given
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Verified Ratio of Inner Diameter to Outer Diameter
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Verified Torsional Moment When Angle of Twist on Basis of Torsional Rigidity is Given
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Verified Torsional Moment When Torsional Shear Stress in a Hollow Shaft is Given
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5 More Design of Hollow Shaft Calculators
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Verified Compressive Stress in the Key
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Verified Diameter of the Shaft When Compressive Stress in the Key is Given
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Verified Diameter of the Shaft When Shear Stress in the Key is Given
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Verified Length of Key When Compressive Stress in the Key is Given
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Verified Length of Key When Shear Stress in the Key is Given
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Verified Shear Stress in the Key
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Verified Torque Transmitted When Compressive Stress in the Key is Given
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Verified Torque Transmitted When Shear Stress in the Key is Given
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Verified Width of Key When Compressive Stress in the Key is Given
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Verified Width of Key When Shear Stress in the Key is Given
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Verified Compressive Stress Of Spigot
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Verified Equivalent Stress By Distortion Energy Theory
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Verified Factor Of Safety For The bi-axial State Of Stress
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Verified Factor Of Safety For The Tri-axial State Of Stress
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Verified Permissible Shear Stress For Cotter
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Verified Permissible Shear Stress For Spigot
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Verified Polar Moment Of Inertia Of Hollow Circular Shaft
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Verified Polar Moment Of Inertia Of Solid Circular Shaft
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Verified Shear Yield Strength by Maximum Shear Stress Theory
Go
Verified Shear Yield Strength By The Maximum Distortion Energy Theory
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Verified Stress Amplitude
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Verified Tensile Stress In Spigot
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Verified Compressive Stress in the Key
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Verified Compressive Stress induced in a Square Key due to Transmitted Torque
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Verified Force on a Key
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Verified Height of Key When Compressive Stress in the Key is Given
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Verified Length of Key When Shear Stress in the Plane is Given
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Verified Length of the Key When Compressive Stress in the Key is Given
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Verified Shaft Diameter When Compressive Stress in the Key is Given
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Verified Shaft Diameter When Force on a Key is Given
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Verified Shear Stress in the Plane
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Verified Shear Stress in the Plane in terms of Torque Transmitted
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Verified Torque Transmitted When Compressive Stress in the Key is Given
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Verified Torque Transmitted When Force on a Keys is Given
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Verified Width of Key When Shear Stress in the Plane is Given
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Verified Commutation Period For Buck Regulator (DCM)
Go
Verified Inductor Value For Buck Regulator (DCM)
Go
Verified Output Current For Buck Regulator (DCM)
Go
Verified Output Voltage For Buck Regulator (DCM)
Go
Verified Commutation Period For Boost Regulator (DCM)
Go
Verified Duty Cycle For Boost Regulator (DCM)
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Verified Inductor Value For Boost Regulator (DCM)
Go
Verified Output Current For Boost Regulator (DCM)
Go
Verified Output Voltage For Boost Regulator (DCM)
Go
Verified Commutation Period For Buck-Boost Regulator (DCM)
Go
Verified Inductor Value For Buck-Boost Regulator (DCM)
Go
Verified Output Current For Buck-Boost Regulator (DCM)
Go
Verified Output Voltage For Buck-Boost Regulator (DCM)
Go
Verified Gain–bandwidth product
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Created a-phase Current (LLGF)
Go
Created a-phase EMF Using Positive Sequence Current (LLGF)
Go
Created a-phase EMF Using Positive Sequence Impedance (LLGF)
Go
Created a-phase EMF Using Positive Sequence Voltage (LLGF)
Go
Created a-phase Voltage Using Zero Sequence Voltage (LLGF)
Go
Created b-phase Current (LLGF)
Go
Created b-phase Voltage (LLGF)
Go
Created b-phase Voltage Using Fault Current (LLGF)
Go
Created b-phase Voltage Using Zero Sequence Current (LLGF)
Go
Created b-phase Voltage Using Zero-Sequence Voltage (LLGF)
Go
Created c-phase Current (LLGF)
Go
Created c-phase Voltage (LLGF)
Go
Created c-phase Voltage Using Fault Current (LLGF)
Go
Created c-phase Voltage Using Zero Sequence Current (LLGF)
Go
Created Fault Current (LLGF)
Go
Created Fault Current Using c-phase Voltage (LLGF)
Go
Created Fault Current Using the b-phase Voltage (LLGF)
Go
Created Fault Impedance Using b-phase Voltage (LLGF)
Go
Created Fault Impedance Using c-phase Voltage (LLGF)
Go
Created Negative Sequence Current Using Negative Sequence Voltage (LLGF)
Go
Created Negative Sequence Voltage Using Negative Sequence Current (LLGF)
Go
Created Positive Sequence Current Using Positive Sequence Voltage (LLGF)
Go
Created Positive Sequence Voltage Using Fault Impedance (LLGF)
Go
Created Zero Sequence Current Using b-phase Voltage (LLGF)
Go
Created Zero Sequence Current Using the c-phase Voltage (LLGF)
Go
Created Zero Sequence Current Using Zero Sequence Voltage (LLGF)
Go
Created Zero Sequence Current Using Zero Sequence Voltage (LLGF)
Go
Created Zero Sequence Voltage Using a-phase Voltage (LLGF)
Go
Created Zero Sequence Voltage Using b-phase Voltage (LLGF)
Go
Created Zero Sequence Voltage Using Fault Impedance (LLGF)
Go
Verified Allowable Load per mm Length of Transverse Fillet Weld
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Verified Force Acting When Shear Stress-induced in the plane that is inclined at an angle θ is Given
Go
Verified Leg of the Weld When Maximum Shear Stress-induced in the Plane is Given
Go
Verified Leg of the Weld When Shear Stress-induced in the Plane is Given
Go
Verified Leg of Weld When Allowable Lod per mm Length of Transverse Fillet Weld is Given
Go
Verified Length of the Weld When Shear Stress-induced in the Plane that is inclined at an Angle θ is Given
Go
Verified length of Weld When Maximum Shear Stress-induced in the Plane is Given
Go
Verified Maximum Shear Stress-induced in the Plane that is Inclined at an Angle θ
Go
Verified Maximum Shear Stress-induced When Allowable Load per mm length of Transverse Fillet Weld is Given
Go
Verified Shear Stress-induced in the Plane that is inclined at an Angle θ to the Horizontal
Go
Created Power developed by synchronous motor
Go
Verified Couple When Torsional Shear Stress-induced in the Throat Area of Welds is Given
Go
Verified Distance of a point in Weld From Center of Gravity When Torsional Shear Stress-induced is Given
Go
Verified Length of Weld When Polar Moment of Inertia of Weld About its Center of Gravity is Given
Go
Verified Load acting on the Weld When Primary Stress-induced in Welds is Given
Go
Verified Polar Moment of Inertia of all Welds about Center of Gravity When Torsional Shear Stress is Given
Go
Verified Polar Moment of Inertia of Welds about its Center of Gravity
Go
Verified Primary Shear Stress
Go
Verified Throat Area of the Weld When Polar Moment of Inertia of Weld About its Center is Given
Go
Verified Throat Area When Primary Shear Stress-induced in the Welds is Given
Go
Verified Torsional Shear Stress-induced in the Throat Area of Welds
Go
EDC (1)
Verified Maximum Efficiency Of A Steam Engine(Semiconductors)
Go
50 More EDC Calculators
Go
Created Angular Speed Using Electrical Efficiency Of Dc Motor
Go
Created Armature Copper Loss Using Overall Efficiency Of Dc Motor
Go
Created Armature Current Using Electrical Efficiency Of Dc Motor
Go
Created Armature Resistance using Overall Efficiency Of Dc Motor
Go
Created Armature Torque Using Electrical Efficiency Of Dc Motor
Go
Created armature torque using mechanical Efficiency Of Dc Motor
Go
Created Constant Losses Using Overall Efficiency Of Dc Motor
Go
Created Converted Power Using Electrical Efficiency Of Dc Motor
Go
Created Converted Power Using Mechanical Efficiency Of Dc Motor
Go
Created Core Loss Using Overall Efficiency Of Dc Motor
Go
Created Current Using Overall Efficiency Of Dc Motor
Go
Created Electrical Efficiency Of Dc Motor
Go
Created field copper loss using Overall Efficiency Of Dc Motor
Go
Created input power using Electrical Efficiency Of Dc Motor
Go
Created Input Power using Overall Efficiency Of Dc Motor
Go
Created Mechanical Efficiency Of Dc Motor
Go
Created Mechanical Loss Using Overall Efficiency Of Dc Motor
Go
Created Output Power Using Mechanical Efficiency Of Dc Motor
Go
Created output power using Overall Efficiency Of Dc Motor
Go
Created Overall Efficiency Of Dc Motor
Go
Created Shunt Field Current Using Overall Efficiency Of Dc Motor
Go
Created Torque Using Mechanical Efficiency Of Dc Motor
Go
Created Total Loss Power Using Overall Efficiency Of Dc Motor
Go
Created Voltage Using Electrical Efficiency Of Dc Motor
Go
Created voltage using Overall Efficiency Of Dc Motor
Go
Created Capacitance For The Parallel RLC Circuit When Q-Factor Is Given
Go
Created Capacitance For The Series RLC Circuit When Q-Factor Is Given
Go
Created Capacitance When The Time Constant And Frequency Is Given
Go
Created Capacitance When The Time Constant Is Given
Go
Created Frequency When Time Constant Is Given
Go
Created Inductance For The Parallel RLC Circuit When Q-Factor Is Given
Go
Created Inductance For The Series RLC Circuit When Q-Factor Is Given
Go
Created Inductance When The Time Constant Is Given
Go
Created Q-factor For The Parallel RLC Circuit
Go
Created Q-factor For The Series RLC Circuit
Go
Created Resistance For The parallel RLC Circuit When Q-Factor Is Given
Go
Created Resistance For The Series RLC Circuit When Q-Factor Is Given
Go
Created Resistance When The Time Constant Is Given
Go
Created Time Constant For The RC Circuit When Resistance Is Given
Go
Created Time Constant For The RC Circuit When The Capacitance Is Given
Go
Created Time Constant For The RC Circuit When The Inductance Is Given
Go
Created Time Constant When The Frequency Is Given
Go
Verified Current Value for Alternating Current
Go
Created EMF Induced in a Rotating Coil
Go
Verified Impedance for LCR Circuit
Go
Verified Impedance for LR Circuit
Go
Verified Impedance for RC Circuit
Go
Verified Power Factor
Go
Verified Resonant Frequency for LCR Circuit
Go
Created Total Flux in Mutual Inductance
Go
18 More Electromagnetic Induction Calculators
Go
Created EMF Induced In Primary Winding
Go
Created EMF Induced In Primary Winding When Input Voltage Is Given
Go
Created EMF Induced In Primary Winding When Voltage Transformation Ratio Is Given
Go
Created EMF Induced In Secondary Winding
Go
Created EMF Induced In Secondary Winding When Output Voltage Is Given
Go
Created EMF Induced In Secondary Winding When Voltage Transformation Ratio Is Given
Go
Created Capacitive Current(ECM)
Go
Created Impedance(ECM)
Go
Created Receiving End Current(ECM)
Go
Created Receiving End Voltage(ECM)
Go
Created Sending End Current Using Impedance(ECM)
Go
Created Sending End Current(ECM)
Go
Created Sending End Voltage(ECM)
Go
Verified Acid Ionization Constant Of Weak Acid
Go
Verified Basic Ionization Constant Of Weak Base
Go
Verified Buffer Capacity
Go
Verified Concentration of Hydronium ion in salt of weak acid and strong base
Go
Verified Concentration of Hydronium ion in Salt of Weak Acid and Weak Base
Go
Verified Concentration Of Hydronium ion In Weak Base And Strong Acid
Go
Verified Concentration Of Hydronium ion Using pH
Go
Verified Concentration of Hydronium ion Using pOH
Go
Verified Degree Of Hydrolysis In Salt Of Weak Acid And Strong Base
Go
Verified Degree of Hydrolysis in Salt of Weak Acid and Weak Base
Go
Verified Degree of Hydrolysis In Salt of Weak Base and Strong Base
Go
Verified Hydrolysis Constant In Strong Acid And Weak Base
Go
Verified Hydrolysis Constant In Weak Acid And Strong Base
Go
Verified Hydrolysis Constant in Weak Acid and Weak Base
Go
Verified Ionic Product Of Water
Go
Verified Maximum pH of Basic Buffer
Go
Verified Maximum pOH of Acidic Buffer
Go
Verified pH In Acidic Buffer At Maxima
Go
Verified pH Of Salt Of Weak Acid And Strong Base
Go
Verified pH of Salt of Weak Acid and Weak base
Go
Verified pH Of Salt Of Weak Base And Strong Base
Go
Verified pH of Strong acid and Strong base
Go
Verified pH Of Water Using Concentration
Go
Verified pOH in Basic Buffer at Maxima
Go
Verified pOH Of Salt Of Strong Base And Weak Acid
Go
Verified pOH of Salt of Weak Acid and Weak Base
Go
Verified pOH Of Salt Of Weak Base And Strong Base
Go
Verified pOH of Strong acid and Strong base
Go
Verified pOH Using Concentration Of Hydroxide ion
Go
Verified Relation between pH and pOH
Go
Verified The pH Value of Ionic Product of Water
Go
Created Equivalent Reactance From Primary Side When Equivalent Impedance From Primary Side Is Given
Go
Created Equivalent Reactance From Secondary Side When Equivalent Impedance From Secondary Side Is Given
Go
Created Equivalent Resistance From Primary Side When Equivalent Impedance From Primary Side Is Given
Go
Created Equivalent Resistance From Primary Side When Secondary Winding Resistance
Go
Created Equivalent Resistance Of Transformer From Primary Side
Go
Created Equivalent Resistance From Secondary Side When Equivalent Impedance From Secondary Side Is Given
Go
Created Equivalent Resistance From Secondary Side When Primary Winding Resistance
Go
Created Equivalent Resistance Of Transformer From Secondary Side
Go
Verified Bending Stress on Extra Full Length Leaves
Go
Verified Deflection of the Spring at Load Point
Go
Verified Force Applied at the End of Spring When Bending Stress on Extra Full Length Leaves is Given
Go
Verified Force Applied at the End of Spring When Force Taken by Extra Full length Leaves is Given
Go
Verified Force Applied at the End of the Spring When Deflection at the End of the Spring is Given
Go
Verified Length of Cantilever When Deflection at the End of the Spring is Given
Go
Verified Length of Cantilever When Deflection of the Spring at Load Point is Given
Go
Verified Length of the Cantilever When Bending Stress on Extra Full Length Leaves is Given
Go
Verified Modulus of Elasticity of Leaf When Deflection of Spring at Load Point is Given
Go
Verified Modulus of Elasticity When Deflection at the End of the Sprig is Given
Go
Verified Number of Extra Full Length Leaves When Bending Stress on Extra Full Length Leaves is Given
Go
Verified Number of Extra Full Length Leaves When Deflection at the End of Spring is Given
Go
Verified Number of Extra Full Length Leaves When Deflection of Spring at Load Point is Given
Go
Verified Number of Graduated Length Leaves When Bending Stress on Extra Full Length Leaves is Given
Go
Verified Number of Graduated length leaves When Deflection at the End of Spring is Given
Go
Verified Number of Graduated Length Leaves When Force Taken by Extra Full Length Leaves is Given
Go
Verified Portion of Force Taken by Extra Full Length When Deflection of Spring at Load Point is Given
Go
Verified Thickness of Each Leaf When Bending Stress on Extra Full Length Leaves is Given
Go
Verified Thickness of Each Leaf When Deflection at the End of the Spring is Given
Go
Verified Width of Each leaf When Bending Stress on Extra Full Length Leaves is Given
Go
Verified Width of Each Leaf When Deflection of Spring at Load Point is Given
Go
Verified Width of Leaf When Deflection at the end of the Spring is Given
Go
2 More Extra Full Length Leaves Calculators
Go
Fault (38)
Created Delta Impedance For Delta Connected Load Using Negative Sequence Voltage
Go
Created Leakage Impedance For Transformer Using Negative Sequence Current
Go
Created Leakage Impedance For transformer Using Negative Sequence Voltage
Go
Created Leakage Impedance For Transformer Using Positive Sequence Current
Go
Created Leakage Impedance For Transformer Using Positive Sequence Voltage
Go
Created Leakage Impedance For Transformer Using Zero Sequence Current
Go
Created Leakage Impedance For transformer Using Zero Sequence Voltage
Go
Created Negative Phase Current For Delta Connected Load
Go
Created Negative Sequence Current For Star Connected Load
Go
Created Negative Sequence Impedance For Delta Connected Load
Go
Created Negative Sequence Impedance For Star Connected Load
Go
Created Negative Sequence Impedance For Transformer
Go
Created Negative Sequence Voltage For Delta Connected Load
Go
Created Negative Sequence Voltage For Star Connected Load
Go
Created Neutral Impedance For Star Connected Load Using Zero Sequence Voltage
Go
Created Positive Sequence Current For Delta Connected Load
Go
Created Positive Sequence Current For Star Connected Load
Go
Created Positive Sequence Impedance For Delta Connected Load
Go
Created Positive Sequence Impedance For Star Connected Load
Go
Created Positive Sequence Impedance For transformer
Go
Created Positive Sequence Voltage (LLF)
Go
Created Positive Sequence Voltage For Delta Connected Load
Go
Created Positive Sequence Voltage For Star Connected Load
Go
Created Sequence Impedance
Go
Created Star Impedance For Star Connected Load Using Negative Sequence Current
Go
Created Star Impedance For Star Connected Load Using Negative Sequence Voltage
Go
Created Star Impedance For Star Connected Load Using Positive Sequence Current
Go
Created Star Impedance For Star Connected Load Using Positive Sequence Voltage
Go
Created Star Impedance For Star Connected Load Using Zero Sequence Current
Go
Created Star Impedance For Star Connected Load Using Zero Sequence Voltage
Go
Created Star Impedance Using Delta Impedance
Go
Created Symmetric Component Current Using Sequence Impedance
Go
Created Symmetric Component Voltage Using Sequence Impedance
Go
Created Zero Sequence current For Star Connected Load
Go
Created Zero Sequence Impedance For Delta Connected Load
Go
Created Zero Sequence Impedance For Star Connected Load
Go
Created Zero Sequence Impedance For transformer
Go
Created Zero Sequence Voltage For Star Connected Load
Go
Verified Diameter Of Fiber
Go
Verified Fiber Attenuation Coefficient
Go
Verified Fiber Length
Go
Verified Gaussian Pulse
Go
Verified Graded Index Fiber
Go
Verified Group Delay
Go
Verified Normalized Frequency
Go
Verified Numerical Aperture
Go
Verified Optical Fiber Dispersion
Go
Verified Optical Pulse
Go
Verified Plane Wave Velocity
Go
Verified Power Loss In Fiber
Go
Verified Ray Optics Critical Angle
Go
Verified Refractive Index Of Fiber Core
Go
Verified Refractive Index Of The Cladding
Go
Verified Total Number Of Modes MN
Go
Verified Absolute Pressure at a Height h
Go
Verified Angle of Inclined Manometer When Pressure at a Point is Given
Go
Verified Angle of Inclined Manometer When Sensitivity is Given
Go
Verified Angle of Jet When Maximum Vertical Elevation is Given
Go
Verified Angle of Jet When Time of Flight of Liquid Jet is Given
Go
Verified Angle of Jet When Time to Reach the Highest Point is Given
Go
Verified Area of Surface Wetted When Center of Pressure is Given
Go
Verified Area of the Surface Wetted When Total Hydrostatic Force is Given
Go
Verified Bulk Modulus When Velocity Of Pressure Wave Is Given
Go
Verified Density of the Liquid When Dynamic Pressure is Given
Go
Verified Depth of Centroid When Center of Pressure is Given
Go
Verified Depth of Centroid When Total Hydrostatic Force is Given
Go
Verified Diameter Of Droplet When Pressure Change Is Given
Go
Verified Diameter of Pipe When Head Loss due to Laminar Flow is Given
Go
Verified Distance Between Buoyancy Point and Center of Gravity When Metacenter Height is Given
Go
Verified Distance Between Plates When Dynamic Viscosity Of A Fluid Is Given
Go
Verified Friction Factor When Frictional Velocity is Given
Go
Verified Head Loss When Efficiency of Hydraulic Transmission is Given
Go
Verified Height Of Fluid 1 When Differential Pressure Between Two Points Is Given
Go
Verified Height Of Fluid 2 When Differential Pressure Between Two Points Is Given
Go
Verified Height Of Liquid When Absolute Pressure Of That Liquid Is Given
Go
Verified Initial Velocity of Liquid Jet When Maximum Vertical Elevation is Given
Go
Verified Initial Velocity When Time of Flight of the Liquid Jet is Given
Go
Verified Initial Velocity When Time to Reach the Highest Point of Liquid is Given
Go
Verified Length of Inclined Manometer When Pressure at a Point is Given
Go
Verified Length of Pipe When Head loss is Given
Go
Verified Mass Density When Velocity Of Pressure Wave Is Given
Go
Verified Mean Velocity When Frictional Velocity is Given
Go
Verified Metacentric Height When Time Period of Rolling is Given
Go
Verified Moment of Inertia about Centroid When Center of Pressure is Given
Go
Verified Moment of Inertia of Waterline Area When Metacentric Height is Given
Go
Verified Normal Stress 2
Go
Verified Pressure using inclined Manometer
Go
Verified Pressure Wave Velocity in Fluids
Go
Verified Radius of Gyration When Time Period of Rolling is Given
Go
Verified Rate of Flow When Head loss In Laminar Flow is Given
Go
Verified Rate of Flow When Hydraulic Transmission Power is Given
Go
Verified Reynolds Number When Frictional Factor of Laminar Flow is Given
Go
Verified Shear Stress When Dynamic Viscosity Of A Fluid Is Given
Go
Verified Specific Weight Of A Liquid When Absolute Pressure Of That liquid At A height is Given
Go
Verified Specific Weight Of Fluid 1 When Differential Pressure Between Two Points Is Given
Go
Verified Specific Weight Of Fluid 2 When Differential Pressure Between Two Points Is Given
Go
Verified Specific Weight of Inclined Manometer Liquid When Pressure at A Point is Given
Go
Verified Specific Weight of Liquid When Head loss Due to Laminar Flow is Given
Go
Verified Specific Weight of Liquid When Hydraulic Transmission Power is Given
Go
Verified Specific Weight of Liquid When Total Hydrostatic Force is given
Go
Verified Specific Weight Of The Liquid When Buoyancy Force Is Given
Go
Verified Surface Area When Surface Tension Is Given
Go
Verified Surface Energy When Surface Tension Is Given
Go
Verified Surface Tension Of Liquid Drop When Change In Pressure Is Given
Go
Verified Surface Tension Of Soap Bubble When Pressure Change Is Given
Go
Verified The diameter Of Soap Bubble When Pressure Change Is Given
Go
Verified Velocity of Fluid When Dynamic Pressure is Given
Go
Verified Velocity Of Moving Plates When Dynamic Viscosity Is Given
Go
Verified Viscous Force When Head loss Due to Laminar Flow is Given
Go
Verified Volume of the Liquid Displaced When Metacentric Height is Given
Go
Verified Volume of the Submerged Object when Buoyancy Force is Given
Go
68 More Fluid Mechanics Calculators
Go
Created Area Of X-Section(2-Phase 4-Wire OS)
Go
Created Constant(2-Phase 4-Wire OS)
Go
Created Line Losses(2-Phase 4-Wire OS)
Go
Created Load Current(2-Phase 4-Wire OS)
Go
Created Maximum Voltage(2-Phase 4-Wire OS)
Go
Created Power Transmitted(2-Phase 4-Wire OS)
Go
Created Resistance(2-Phase 4-Wire OS)
Go
Created Volume Of Conductor Material(2-Phase 4-Wire OS)
Go
Created Area Of X-Section(3-Phase 4-Wire OS)
Go
Created Constant(3-Phase 4-Wire OS)
Go
Created Line Losses(3-Phase 4-Wire OS)
Go
Created Load Current(3-Phase 4-Wire OS)
Go
Created Maximum Voltage(3-Phase 4-Wire OS)
Go
Created Power Transmitted(3-Phase 4-Wire OS)
Go
Created Resistance(3-Phase 4-Wire OS)
Go
Created Volume Of Conductor Material(3-Phase 4-Wire OS)
Go
Created Frequency When EMF Induced In Primary Winding is Given
Go
Created Frequency When EMF Induced In Secondary Winding is Given
Go
Verified Black bodies heat exchange by radiation
Go
Verified Heat Exchange By Radiation Due To Geometric Arrangement
Go
Verified Non Ideal Body Surface Emittance
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12 More Heat Transfer Calculators
Go
Verified Axial Deflection of the Spring Due to Axial Load When Stiffness of the Spring is Given
Go
Verified Axial Spring Force When Stiffness of the Spring is Given
Go
Verified Diameter of Spring Wire When Load Stress Equation is Given
Go
Verified Diameter of the Wire When Spring Index is Given
Go
Verified Inside Diameter of the Spring Coil When Mean Coil Diameter is Given
Go
Verified Load Stress Equation
Go
Verified Mean Coil Diameter
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Verified Mean Coil Diameter When Spring Index is Given
Go
Verified Outside Diameter of the Spring Coil When Mean Coil Diameter is Given
Go
Verified Solid Length of the Spring
Go
Verified Spring Index
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Verified Spring Index When Load Stress Equation is Given
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Verified Stiffness of the Spring
Go
Verified Total Number of Coils When Solid Length of the Spring is Given
Go
Verified Bending Moment Applied on the Spring When Bending Stress is Given
Go
Verified Bending Stress in the Spring
Go
Verified Diameter of the Spring Wire When Bending Stress in the Spring is Given
Go
Verified Diameter of the Spring Wire When Stiffness of Helical Torsion Spring is Given
Go
Verified Mean Coil Diameter When Stiffness of Helical Torsion Spring is Given
Go
Verified Modulus of Elasticity When Stiffness of Helical Torsion Spring is Given
Go
Verified Number of Coils of the Spring When Stiffness of Helical Torsion Spring is Given
Go
Verified Stiffness of Helical Torsion Spring
Go
Verified Stress Concentration Factor When Bending Stress in the Spring is Given
Go
Verified Number Of Spectral Lines
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17 More Hydrogen spectrum Calculators
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Created Impedance Of Primary Winding
Go
Created Impedance Of Primary Winding When Input Voltage Is Given
Go
Created Impedance Of Secondary Winding
Go
Created Impedance Of Secondary Winding When Output Voltage Is Given
Go
Created Characteristic Impedance For Incident Waves
Go
Created Incident Current
Go
Created Incident Current Using Reflected And Transmitted Current
Go
Created Incident Voltage
Go
Created Incident Voltage Using Reflected And Transmitted Voltage
Go
Created Armature Current When Power Is Given
Go
Created Breakdown Slip Of An Induction Motor
Go
Created Field Current When Load Current Is Given
Go
Created Force By A Linear Induction Motor
Go
Created Frequency When The Number of Poles Is Given
Go
Created Gross Torque When Mechanical Power Is Given
Go
Created Gross Torque When Synchronous Speed Is Given
Go
Created Induced Voltage When Power Is Given
Go
Created Load Current
Go
Created Maximum Running Torque
Go
Created Motor Efficiency Using Slip
Go
Created Motor Speed
Go
Created Motor Speed When Angular Speed Is Given
Go
Created Motor Speed When Efficiency Is Given
Go
Created Number Of Poles When Synchronous Speed Is Given
Go
Created Reactance When Slip Is Given
Go
Created Resistance When Slip Is Given
Go
Created Slip
Go
Created Slip When Efficiency Is Given
Go
Created Slip When Frequency Is Given
Go
Created Slip When Input Power Is Given
Go
Created Slip When The Copper Loss Is Given
Go
Created Starting Torque of Inductance Motor
Go
Created Synchronous Speed When Efficiency Is Given
Go
Created Synchronous Speed When Gross Torque Is Given
Go
Created Synchronous Speed When Mechanical Power Is Given
Go
Created Synchronous Speed When Motor Speed Is Given
Go
Created Torque In Running Condition
Go
Created Voltage
Go
6 More Induction Motor Calculators
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Created Input Voltage When EMF Induced In Primary Winding Is Given
Go
K (6)
Created Length Of Wire Using K(Two-Wire One Conductor Earthed)
Go
Created Line Losses Using K(Two-Wire One Conductor Earthed)
Go
Created Maximum Voltage Using K(Two-Wire One Conductor Earthed)
Go
Created Power Transmitted Using K(Two-Wire One Conductor Earthed)
Go
Created Resistivity Using K(Two-Wire One Conductor Earthed)
Go
Created Volume Using K(Two-Wire One Conductor Earthed)
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K (1)
Created Volume Using K(Two-Wire Mid-point Earthed)
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K (6)
Created Length Using Constant(DC 3-wire)
Go
Created Line Losses Using Constant(DC 3-wire)
Go
Created Maximum Power Using Constant(DC 3-wire)
Go
Created Power Transmitted Using Constant(DC 3-wire)
Go
Created Resistivity Using Constant(DC 3-wire)
Go
Created Volume Of Conductor Material Using Constant(DC 3-wire)
Go
K (11)
Created Area Of X-Section Using Constant (1-Phase 2-Wire US)
Go
Created Length Of Wire Using Constant (1-Phase 2-Wire US)
Go
Created Line Losses Using Constant (1-Phase 2-Wire US)
Go
Created Load Current Using Constant (1-Phase 2-Wire US)
Go
Created Maximum Voltage Using Constant (1-Phase 2-Wire US)
Go
Created Power Factor Using Constant (1-Phase 2-Wire US)
Go
Created Power Transmitted Using Constant (1-Phase 2-Wire US)
Go
Created Resistance Using Constant (1-Phase 2-Wire US)
Go
Created Resistivity Using Constant (1-Phase 2-Wire US)
Go
Created RMS Voltage Using Constant (1-Phase 2-Wire US)
Go
Created Volume Of Conductor Material Using Constant (1-Phase 2-Wire US)
Go
K (1)
Created Volume Of Conductor Material Using Constant(3-phase 4-wire OS)
Go
Created a-phase Current (LLF)
Go
Created b-phase Current (LLF)
Go
Created b-phase Current Using Fault Impedance (LLF)
Go
Created b-phase Voltage (LLF)
Go
Created b-phase Voltage Using c-phase Current (LLF)
Go
Created c-phase Current Using Fault Impedance (LLF)
Go
Created c-phase Current(LLF)
Go
Created c-phase Voltage (LLF)
Go
Created c-phase Voltage Using c-phase Current (LLF)
Go
Created Fault Impedance Using b-phase Current (LLF)
Go
Created Fault Impedance Using c-phase Current (LLF)
Go
Created Fault Impedance Using Positive Sequence Current (LLF)
Go
Created Negative Sequence Current(LLF)
Go
Created Negative Sequence Voltage (LLF)
Go
Created Positive Sequence Current (LLF)
Go
Created Positive Sequence Voltage (LLF)
Go
Created Zero Sequence Current(LLF)
Go
Created Zero Sequence Voltage(LLF)
Go
Created Area Of X-section Using Line Losses(Two-Wire One Conductor Earthed)
Go
Created Length Of Line Using Line Losses(Two-Wire One Conductor Earthed)
Go
Created Load Current Using Line Losses(DC Two-Wire OS)
Go
Created Maximum Voltage Using Line Losses(Two-Wire One Conductor Earthed)
Go
Created Resistance Using Line Losses(Two-Wire One Conductor Earthed)
Go
Created Resistivity Using Line Losses(Two-Wire One Conductor Earthed)
Go
Created Transmitted Power Using Line Losses(Two-Wire One Conductor Earthed)
Go
Created Area Of X-section Using Line Losses(Two-Wire Mid-point Earthed)
Go
Created Length Of Wire Using Line Losses(Two-Wire Mid-point Earthed)
Go
Created Load Current Using Line Losses(Two-Wire Mid-point Earthed)
Go
Created Maximum Voltage Using Line Losses(Two-Wire Mid-point Earthed)
Go
Created Power Transmitted Using Line Losses(Two-Wire Mid-point Earthed)
Go
Created Resistance Using Line Losses(Two-Wire Mid-point Earthed)
Go
Created Resistivity Using Line Losses(Two-Wire Mid-point Earthed)
Go
Created Area Of X-section Using Line Losses(DC 3-wire)
Go
Created Length Using Line Losses(DC 3-wire)
Go
Created Load Current Using Line Losses(DC 3-wire)
Go
Created Maximum Voltage Using Line Losses(DC 3-wire)
Go
Created Power Transmitted Using Line Losses(DC 3-wire)
Go
Created Resistance Using Line Losses(DC 3-wire)
Go
Created Resistivity Using Line Losses(DC 3-wire)
Go
Created Area Of X-Section Using Line Losses (1-Phase 2-Wire US)
Go
Created Constant Using Line Losses (1-Phase 2-Wire US)
Go
Created Length Using Line Losses (1-Phase 2-Wire US)
Go
Created Load Current Using Line Losses (1-Phase 2-Wire US)
Go
Created Maximum Voltage Using Line Losses (1-Phase 2-Wire US)
Go
Created Power Factor Using Line Losses (1-Phase 2-Wire US)
Go
Created Power Transmitted Using Line Losses (1-Phase 2-Wire US)
Go
Created Resistance Using Line Losses (1-Phase 2-Wire US)
Go
Created Resistivity Using Line Losses (1-Phase 2-Wire US)
Go
Created RMS Voltage Using Line Losses (1-Phase 2-Wire US)
Go
Created Volume Of Conductor Material Using Line Losses (1-Phase 2-Wire US)
Go
Created Area Of X-Section Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Created Constant Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Created Length Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Created Load Current Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Created Maximum Voltage Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Created Power Factor Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Created Power Transmitted Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Created Resistance Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Created Resistivity Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Created RMS Voltage Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Created Volume Of Conductor Material Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Created Area Of X-Section Using Line Losses (1-Phase 2-Wire OS)
Go
Created Constant Using Line Losses (1-Phase 2-Wire OS)
Go
Created Length Using Line Losses (1-Phase 2-Wire OS)
Go
Created Load Current Using Line Losses (1-Phase 2-Wire OS)
Go
Created Maximum Voltage Using Line Losses (1-Phase 2-Wire OS)
Go
Created Power Factor Using Line Losses (1-Phase 2-Wire OS)
Go
Created Power Transmitted Using Line Losses (1-Phase 2-Wire OS)
Go
Created Resistance Using Line Losses (1-Phase 2-Wire OS)
Go
Created Resistivity Using Line Losses (1-Phase 2-Wire OS)
Go
Created RMS Voltage Using Line Losses (1-Phase 2-Wire OS)
Go
Created Volume Of Conductor Material Using Line Losses (1-Phase 2-Wire OS)
Go
Created Area Of X-Section Using Line Losses (2-Phase 4-Wire OS)
Go
Created Constant Using Line Losses (2-Phase 4-Wire OS)
Go
Created Length Using Line Losses (2-Phase 4-Wire OS)
Go
Created Load Current Using Line Losses (2-Phase 4-Wire OS)
Go
Created Maximum Voltage Using Line Losses (2-Phase 4-Wire OS)
Go
Created Power Factor Using Line Losses (2-Phase 4-Wire OS)
Go
Created Power Transmitted Using Line Losses (2-Phase 4-Wire OS)
Go
Created Resistance Using Line Losses (2-Phase 4-Wire OS)
Go
Created Resistivity Using Line Losses (2-Phase 4-Wire OS)
Go
Created RMS Voltage Using Line Losses (2-Phase 4-Wire OS)
Go
Created Volume Of Conductor Material Using Line Losses (2-Phase 4-Wire OS)
Go
Created Area Of X-Section Using Line Losses (1-Phase 3-Wire OS)
Go
Created Constant Using Line Losses (1-Phase 3-Wire OS)
Go
Created Length Using Line Losses (1-Phase 3-Wire OS)
Go
Created Load Current Using Line Losses (1-Phase 3-Wire OS)
Go
Created Maximum Voltage Using Line Losses (1-Phase 3-Wire OS)
Go
Created Power Factor Using Line Losses (1-Phase 3-Wire OS)
Go
Created Power Transmitted Using Line Losses (1-Phase 3-Wire OS)
Go
Created Resistance Using Line Losses (1-Phase 3-Wire OS)
Go
Created Resistivity Using Line Losses (1-Phase 3-Wire OS)
Go
Created RMS Voltage Using Line Losses (1-Phase 3-Wire OS)
Go
Created Volume Of Conductor Material Using Line Losses (1-Phase 3-Wire OS)
Go
Created Angle Of PF Using Line Losses (2-Phase 3-Wire OS)
Go
Created Area Of X-Section Using Line Losses (2-Phase 3-Wire OS)
Go
Created Length Using Line Losses (2-Phase 3-Wire OS)
Go
Created Maximum Voltage Using Line Losses (2-Phase 3-Wire OS)
Go
Created Power Factor Using Line Losses (2-Phase 3-Wire OS)
Go
Created Resistance Using Line Losses (2-Phase 3-Wire OS)
Go
Created Resistivity Using Line Losses (2-Phase 3-Wire OS)
Go
Created RMS Voltage Using Line Losses (2-Phase 3-Wire OS)
Go
Created Transmitted Power Using Line Losses (2-Phase 3-Wire OS)
Go
Created Angle Of Pf Using Line Losses (2-Phase 3-Wire US)
Go
Created Area Of X-Section Using Line Losses (2-Phase 3-Wire US)
Go
Created Length Using Line Losses (2-Phase 3-Wire US)
Go
Created Maximum Voltage Using Line Losses (2-Phase 3-Wire US)
Go
Created Power Factor Using Line Losses (2-Phase 3-Wire US)
Go
Created Resistance Using Line Losses (2-Phase 3-Wire US)
Go
Created Resistivity Using Line Losses (2-Phase 3-Wire US)
Go
Created RMS Voltage Using Line Losses (2-Phase 3-Wire US)
Go
Created Transmitted Power Using Line Losses (2-Phase 3-Wire US)
Go
Created Maximum Voltage Using Load Current(Two-Wire One Conductor Earthed)
Go
Created Transmitted Power Using Load Current(Two-Wire One Conductor Earthed)
Go
Created Maximum Voltage Using Load Current(Two-Wire Mid-point Earthed)
Go
Created Power Transmitted Using Load Current(Two-Wire Mid-point Earthed)
Go
Created Maximum Power Using Load Current(DC 3-wire)
Go
Created Power Transmitted Using Load Current(DC 3-wire)
Go
Created Area Of X-Section Using Load Current (1-Phase 2-Wire US)
Go
Created Constant Using Load Current (1-Phase 2-Wire US)
Go
Created Length Using Load Current (1-Phase 2-Wire US)
Go
Created Line Losses Using Load Current (1-Phase 2-Wire US)
Go
Created Maximum Voltage Using Load Current (1-Phase 2-Wire US)
Go
Created Power Factor Using Load Current (1-Phase 2-Wire US)
Go
Created Power Transmitted Using Load Current (1-Phase 2-Wire US)
Go
Created Resistivity Using Load Current (1-Phase 2-Wire US)
Go
Created RMS Voltage Using Load Current (1-Phase 2-Wire US)
Go
Created Volume Of Conductor Material Using Load Current (1-Phase 2-Wire US)
Go
Created Area Of X-Section Using Load Current (1-Phase 2-Wire Mid-Point OS)
Go
Created Constant Using Load Current (1-Phase 2-Wire Mid-Point OS)
Go
Created Length Using Load Current (1-Phase 2-Wire Mid-Point OS)
Go
Created Line Losses Using Load Current (1-Phase 2-Wire Mid-Point OS)
Go
Created Maximum Voltage Using Load Current (1-Phase 2-Wire Mid-Point OS)
Go
Created Power Factor Using Load Current (1-Phase 2-Wire Mid-Point OS)
Go
Created Power Transmitted Using Load Current (1-Phase 2-Wire Mid-Point OS)
Go
Created Resistance Using Load Current (1-Phase 2-Wire Mid-Point OS)
Go
Created Resistivity Using Load Current (1-Phase 2-Wire Mid-Point OS)
Go
Created RMS Voltage Using Load Current (1-Phase 2-Wire Mid-Point OS)
Go
Created Volume Of Conductor Material Using Load Current (1-Phase 2-Wire Mid-Point OS)
Go
Created Area Of X-Section Using Load Current (1-Phase 2-Wire OS)
Go
Created Constant Using Load Current (1-Phase 2-Wire OS)
Go
Created Length Using Load Current (1-Phase 2-Wire OS)
Go
Created Line Losses Using Load Current (1-Phase 2-Wire OS)
Go
Created Maximum Voltage Using Load Current (1-Phase 2-Wire OS)
Go
Created Power Factor Using Load Current (1-Phase 2-Wire OS)
Go
Created Power Transmitted Using Load Current (1-Phase 2-Wire OS)
Go
Created Resistance Using Load Current (1-Phase 2-Wire OS)
Go
Created Resistivity Using Load Current (1-Phase 2-Wire OS)
Go
Created RMS Voltage Using Load Current (1-Phase 2-Wire OS)
Go
Created Volume Of Conductor Material Using Load Current (1-Phase 2-Wire OS)
Go
Created Area Of X-Section Using Load Current (2-Phase 4-Wire OS)
Go
Created Constant Using Load Current (2-Phase 4-Wire OS)
Go
Created Length Using Load Current (2-Phase 4-Wire OS)
Go
Created Line Losses Using Load Current (2-Phase 4-Wire OS)
Go
Created Maximum Voltage Using Load Current (2-Phase 4-Wire OS)
Go
Created Power Factor Using Load Current (2-Phase 4-Wire OS)
Go
Created Power Transmitted Using Load Current (2-Phase 4-Wire OS)
Go
Created Resistance Using Load Current (2-Phase 4-Wire OS)
Go
Created Resistivity Using Load Current (2-Phase 4-Wire OS)
Go
Created RMS Voltage Using Load Current (2-Phase 4-Wire OS)
Go
Created Volume Of Conductor Material Using Load Current (2-Phase 4-Wire OS)
Go
Created Area Of X-Section Using Load Current (1-Phase 3-Wire OS)
Go
Created Constant Using Load Current (1-Phase 3-Wire OS)
Go
Created Length Using Load Current (1-Phase 3-Wire OS)
Go
Created Line Losses Using Load Current (1-Phase 3-Wire OS)
Go
Created Maximum Voltage Using Load Current (1-Phase 3-Wire OS)
Go
Created Power Factor Using Load Current (1-Phase 3-Wire OS)
Go
Created Power Transmitted Using Load Current (1-Phase 3-Wire OS)
Go
Created Resistance Using Load Current (1-Phase 3-Wire OS)
Go
Created Resistivity Using Load Current (1-Phase 3-Wire OS)
Go
Created RMS Voltage Using Load Current (1-Phase 3-Wire OS)
Go
Created Volume Of Conductor Material Using Load Current (1-Phase 3-Wire OS)
Go
Created Angle Of PF Using Load Current(3-phase 3-wire OS)
Go
Created Maximum Voltage Using Load Current(3-phase 3-wire OS)
Go
Created Power Factor Using Load Current(3-phase 3-wire OS)
Go
Created RMS Voltage Using Load Current(3-phase 3-wire OS)
Go
Created Transmitted Power Using Load Current(3-phase 3-wire OS)
Go
Created Load Current In Each Outer (2-phase 3-wire OS)
Go
Created Load Current Of Neutral Wire (2-phase 3-wire OS)
Go
Created Maximum Voltage Using Load Current (2-phase 3-wire OS)
Go
Created Power Transmitted Using Load Current (2-phase 3-wire OS)
Go
Created RMS Voltage Using Load Current (2-phase 3-wire OS)
Go
Created Angle Of PF Using Load Current (3-phase 4-wire OS)
Go
Created Maximum Voltage Using Load Current (3-phase 4-wire OS)
Go
Created Power Factor Using Load Current (3-phase 4-wire OS)
Go
Created Power Transmitted Using Load Current (3-phase 4-wire OS)
Go
Created RMS Voltage Using Load Current (3-phase 4-wire OS)
Go
Created Angle Of PF Using Load Current (1-phase 3-wire US)
Go
Created Maximum Voltage Using Load Current (1-phase 3-wire US)
Go
Created RMS Voltage Using Load Current (1-phase 3-wire US)
Go
Created Transmitted Power Using Load Current (1-phase 3-wire US)
Go
1 More Load Current Calculators
Go
Created Admittance Using Characteristic Impedance (LTL)
Go
Created Admittance Using Propagation Constant (LTL)
Go
Created Capacitance Using Surge Impedance (LTL)
Go
Created Characteristic Impedance (LTL)
Go
Created Characteristic Impedance Using Sending End Current (LTL)
Go
Created Characteristic Impedance Using Sending End Voltage (LTL)
Go
Created Impedance Using Characteristic Impedance (LTL)
Go
Created Impedance Using Propagation Constant (LTL)
Go
Created Inductance Using Surge Impedance (LTL)
Go
Created Propagation Constant (LTL)
Go
Created Receiving End Angle (LTL)
Go
Created Receiving End Angle Using Hyperbolic Sine(LTL)
Go
Created Receiving End Current Using Sending End Current (LTL)
Go
Created Receiving End Current Using Sending End Voltage (LTL)
Go
Created Receiving End Voltage Using Sending End Current (LTL)
Go
Created Receiving End Voltage Using Sending End Voltage (LTL)
Go
Created Sending End Current (LTL)
Go
Created Sending End Voltage (LTL)
Go
Created Surge Impedance (LTL)
Go
Verified Inner Diameter of Cylinder When Thickness of Boiler Shell is Given
Go
Verified Internal Pressure When Thickness of Boiler Shell is Given
Go
Verified Permissible Tensile Stress for Cylinder when Thickness of Boiler Shell is Given
Go
Verified Thickness of Boiler Shell
Go
Created Losses(ECM)
Go
Created Resistance Using Losses(ECM)
Go
Created Sending End Current Using Losses(ECM)
Go
Verified Power Transmitted
Go
Verified Thickness Of Cotter Joint
Go
11 More Machine Design Calculators
Go
Created Maximum Flux Density When Primary Winding Is Given
Go
Created Maximum Flux Density When Secondary Winding Is Given
Go
Created Maximum Flux In Core When Primary Winding Is Given
Go
Created Maximum Flux In Core When Secondary Winding Is Given
Go
Verified Diameter of the Shaft When Permissible Value of Maximum Principle Stress is Given
Go
Verified Factor of Safety When Permissible Value of Maximum Principle Stress is Given
Go
Verified Permissible Value of Maximum Principle Stress
Go
Verified Permissible Value of Maximum Principle Stress in terms of Factor of Safety
Go
Verified Yield Stress in Shear When Permissible Value of Maximum Principle Stress is Given
Go
Verified Equivalent Bending Moment
Go
Verified Factor of Safety When Permissible Value of Maximum Shear Stress is Given
Go
Verified Permissible Value of Maximum Shear Stress
Go
Verified Principle Shear Stress
Go
Verified Torsional Moment When Equivalent Bending Moment is Given
Go
Verified Yield Strength in Shear (maximum shear Stress theory)
Go
3 More Maximum Shear Stress Theory Calculators
Go
Verified Absolute Static Error of quantity A
Go
Verified Angular Deflection Of Spring
Go
Verified Area of Capillary Tube
Go
Verified Area of the Bulb
Go
Verified Average Deviation
Go
Verified Co-efficient of volumetric Expansion
Go
Verified Current at Full-scale reading
Go
Verified Erroneous Quantity
Go
Verified Flat Spiral Spring Controlling Torque
Go
Verified Full-Scale Deviation
Go
Verified Full-scale Voltage Reading
Go
Verified Instrumentation Span
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Verified Inverse Sensitivity or Scale Factor
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Verified Largest Reading(Xmax)
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Verified Length Of Spring
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Verified Length of the Capillary Tube
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Verified Location of Point
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Verified Magnitude of Input
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Verified Magnitude of Output Response
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Verified Magnitude Of Physical Quantity
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Verified Maximum Displacement Deviation
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Verified Maximum Resistance deviation
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Verified Measured Value Of the quantity
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Verified Nominal Value
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Verified Numerical Ratio
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Verified Percent Linearity
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Verified Percentage Error
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Verified Power Consumed at Full-Scale Reading
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Verified Relative Limiting Error
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Verified Relative Static Error
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Verified Resistance Of Meter
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Verified Sensitivity
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Verified Sharpness Of Curve
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Verified Smallest reading(Xmin)
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Verified Standard Deviation for Normal Curve
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Verified True Quantity
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Verified True Value of Quantity(At)
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Verified Width of Spring
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Verified Youngs Modulus Of Flat Spring
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32 More MEASURING INSTRUMENTATION Calculators
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Verified Amplifier Gain of Tunnel Diode
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Verified Average diode temperature in °K
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Verified Average time to traverse the emitter to collector
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Verified Bandwidth of Negative Resistance Parametric Amplifier
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Verified Bandwidth of Parametric Up-Converter
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Verified Base Resistance
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Verified Base Transit Time
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Verified Characteristic impedance of circulator
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Verified Collector Depletion Layer Charging Time
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Verified Collector Depletion layer Transit Time
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Verified Collector Frequency Capacitance
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Verified Cut-off frequency MESFET
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Verified Cut-Off Frequency Of microwave
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Verified Diode temperature
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Verified Drain Resistance MESFET
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Verified Dynamic Q-factor
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Verified Emitter Base Junction Charging Time
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Verified Emitter To Collector Delay Time
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Verified Emitter To Collector Distance
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Verified Emitter-Base Junction Charging Time
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Verified Figure Of Merit For Nonlinear Capacitor
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Verified Figure Of Merit of Non-linear Capacitor
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Verified First Fourier component of elastance
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Verified Gain-Degradation Factor
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Verified Gate length
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Verified Gate metallization resistance MESFET
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Verified Gate to source capacitance MESFET
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Verified Idler frequency
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Verified Input resistance MESFET
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Verified Junction capacitance at voltage V
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Verified Magnitude Of Negative Resistance
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Verified Maximum Allowable Applied Voltage
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Verified Maximum Current Of Device
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Verified Maximum frequency of oscillations
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Verified Maximum frequency of oscillations MESFET
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Verified Negative Conductance Of Diode
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Verified Negative Resistance Amplifier's Power Gain
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Verified Noise Figure Of double side band
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Verified Noise Figure Of Parametric Up-Converter
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Verified Noise Figure Of single side band
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Verified Output Frequency in Up-Convertor
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Verified Output Resistance Of Idler Generator
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Verified Output Resistance Of Signal Generator
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Verified Power gain for a parametric Up-Converter
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Verified Power gain of a demodulator
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Verified Power gain of a modulator
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Verified Pumping frequency
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Verified Q-factor at voltage ‘V’
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Verified Q-Factor of Up-Converter
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Verified Ratio negative resistance to series resistance
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Verified Reactive Impedence
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Verified Reflection Co-Efficient from circulator to tunnel diode
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Verified Room Temperature
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Verified Saturation Drift Velocity
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Verified Series Resistance Of p-n Junction Diode
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Verified Series resistance of the diode
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Verified Signal frequency
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Verified Source Resistance MESFET
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Verified Static Figure Of Merit Cut-off Frequency
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Verified Total Series Resistance At Fi
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Verified Total Series Resistance At Fs
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Verified Transconductance MESFET
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Verified Tunnel Diode Output Power
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Verified Accelerating Anode Voltage
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Verified Anode Current
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Verified Anode Voltage
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Verified Attenuation Due To Conductor Losses
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Verified Attenuation Due To Dielectric
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Verified Average distance between the cavities
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Verified Average Microwave Voltage In Buncher Gap
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Verified Average Transit Angle
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Verified Average Transit Time Through The Buncher Gap
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Verified Beam Coupling Coefficient Of Input Cavity Gap
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Verified Beam Loading Conductance
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Verified Buncher Cavity Gap
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Verified Bunching Parameter Of Klystron
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Verified Capacitance at the vane tips
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Verified Carrier Frequency In Spectral Line
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Verified Cathode Radius
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Verified Cavity Gap Voltage
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Verified Cavity Quality Factor
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Verified Characteristic Admittance
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Verified circuit efficiency in the magnetron
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Verified Conductance of the resonator
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Verified Conversion Loss Of Mixture
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Verified Critical (or Hull Cut-off) Magnetic field
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Verified Cu Losses Of Cavity
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Verified Current Arriving At Catcher Cavity Gap
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Verified Cyclotron Angular frequency
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Verified D.C Grid Voltage
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Verified D.C Phase Constant Of Electron Beam
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Verified D.C Transit Angle
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Verified D.C Transit-Time
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Verified Distortion Line
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Verified Drift Space Length
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Verified Electric Field Max
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Verified Electric Field Minimum
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Verified Electronic efficiency
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Verified External Q-factor
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Verified First Modulating Frequency in Modulation Linearity
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Verified Fundamental Of Catcher Gap Voltage
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Verified Gain of TWT
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Verified Group Velocity
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Verified Hull Cut-off voltage
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Verified Incident Voltage
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Verified Induced Current In Catcher Cavity
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Verified Induced Current In The Walls Of Catcher Cavity
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Verified Insertion Loss
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Verified Integer value
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Verified Klystron Efficiency
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Verified Length Of Slow Wave Structure
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Verified Load Conductance
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Verified Magnetron Phase
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Verified Magnitude Of Microwave Signal At Input Cavity
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Verified Mismatched Loss
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Verified Modulation Linearity
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Verified Mutual Conductance Of Klystron Amplifier
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Verified Noise Figure In IF Amplifier
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Verified Noise Figure Of Mixture
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Verified Noise Ratio
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Verified Number Of Resonant Cavities
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Verified Numerical Number
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Verified Optimum Transit Time
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Verified Overall Noise Figure
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Verified Phase Constant for N-cavities
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Verified Phase Velocity
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Verified Plasma frequency
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Verified Power Lost In Anode Circuit
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Verified power obtained from dc power supply
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Verified Power Standing Wave Ratio
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Verified Q-factor Of Beam Loading
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Verified Q-Factor Of Catcher Wall
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Verified Q-Factor Of External Load
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Verified Q-Factor Of Loaded Catcher Cavity
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Verified Q-factor of loaded resonator circuit
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Verified Quality Factor Of Parallel Resonant Circuit
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Verified Receiver Sensitivity
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Verified Rectangular Microwave Pulse Peak Power
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Verified Reduced Plasma Frequency
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Verified Reflected Voltage
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Verified Reflection Coefficient
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Verified Repeller Voltage
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Verified Repetition Frequency Of Pulse
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Verified Resonant Frequency Of Cavity
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Verified Retarding Field
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Verified Return Loss
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Verified RF power induced into the anode circuit
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Verified RF Pulse Width(Teff)
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Verified Round-trip D.C Transit Time In Repeller Space
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Verified Second Modulating Frequency in Modulation Linearity
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Verified Shunt Resistance in Parallel Resonant Circuit
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Verified Skin Depth
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Verified Space Charge Reduction Factor
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Verified Spectral Line Frequency
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Verified Total Conductance of Reflex Klystron (G)
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Verified Travelling Wave Tube Gain Parameter
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Verified Unloaded Q-factor
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Verified Velocity Of Electron In Grid
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Verified Voltage Standing Wave Ratio
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Verified Base current when saturation current in DC is given
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Verified Collector current when saturation current is given
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Verified Collector to emitter voltage at saturation
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Verified Emitter current through minor carrier concentration
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Verified Forced common-emitter current gain
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Verified Saturation current
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Verified Saturation current when doping concentration is given
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Verified Thermal equilibrium value of minority charge carrier
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Verified Body effect in NMOS
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Verified Body effect in PMOS
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Verified Conductance of channel of MOSFET when Vgs is given
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Verified Conductance of channel of MOSFETs
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Verified Current entering drain terminal of MOSFET
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Verified Current entering drain terminal of MOSFET at saturation
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Verified Current entering drain terminal of MOSFET when Vgs is given
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Verified Current flowing through the induced channel in the transistor
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Verified Current flowing through the induced channel in the transistor when Vgs is given
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Created Differential input signal of the non-inverting configuration
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Verified Drain current when device parameter is given
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Verified Drain current when MOSFET operates as a voltage-controlled current source
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Verified Drain current when MOSFET operates as a voltage-controlled current source in terms of Vov
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Verified Drain current without channel-length modulation of MOSFET
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Verified Drain saturation current of MOSFET
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Verified Drain saturation current of MOSFET when Vgs is given
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Verified Effective voltage of MOSFET
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Verified Electric field across the length of the channel of NMOS transistor
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Verified Electron drift velocity of the channel in NMOS transistor
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Verified Fabrication process parameter of NMOS
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Verified Magnitude of the electron charge in the channel of MOSFET
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Verified MOSFET as linear resistance
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Verified MOSFET as linear resistance when aspect ratio is given
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Verified MOSFET as linear resistance when Vgs is given
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Verified MOSFET transconductance parameter
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Verified MOSFET transconductance parameter in terms of process transconductance
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Verified Output resistance of current source of MOSFET
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Verified Output resistance of current source when device parameter is given
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Verified Output resistance of current source when drain current is given
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Verified Overdrive Voltage of MOSFET
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Verified Oxide capacitance of MOSFETs
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Verified Positive voltage when device parameter is given in MOSFET
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Verified Positive voltage when the channel length is given in MOSFET
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Verified Process transconductance parameter of MOSFET
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Verified Saturation voltage of MOSFET
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Verified Total capacitance between gate and channel of MOSFETs
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Verified Transistor aspect ratio
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Verified Bending Stress in the Plate(Extra Full Length)
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Verified Bending Stress in the Plate(Graduated-length Leaves)
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Verified Deflection at the Load Point (Graduated Length Leaves)
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Verified Force Applied at the End of Spring When Bending Stress on the Graduated Length Leaves is Given
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Verified Force Applied at the End of Spring When Force Taken by Graduated length Leaves is Given
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Verified Force Taken by Extra Full Length Leaves in Terms of Number of Leaves
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Verified Force Taken by Full length Leaves When Force at the end of the Spring is Given
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Verified Force Taken by the Full Length Leaves When Bending Stress in the Plate(Extra Full Length) is Given
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Verified Force Taken by the Graduated length Leaves When Bending Stress in the Plate is Given
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Verified Force Taken by the Graduated length Leaves When Deflection at the Load Point is Given
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Verified Force Taken by the Graduated Length Leaves When Force Applied at the End of the Spring is Given
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Verified Length of Cantilever When Bending Stress in the Plate is Given
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Verified Length of Cantilever When Bending Stress in the Plate(Extra Full Length) is Given
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Verified Length of Cantilever When Bending Stress on the Graduated Length Leaves is Given
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Verified Length of Cantilever When Deflection at the Load Point(Graduated Length Leaves) is Given
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Verified Modulus of Elasticity of leaf When Deflection at the Load Point (Graduated Length Leaves) is Given
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Verified Number of Extra Full Length Leaves When Bending Stress on Graduated Length Leaves is Given
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Verified Number of Extra Full Length Leaves When Force Taken by Graduated Length Leaves is Given
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Verified Number of Full Length Leaves When Bending Stress in the Plate(Extra Full Length) is Given
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Verified Number of Graduated length leaves When Bending Stress in the Plate is Given
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Verified Number of Graduated length Leaves When Bending Stress on the Graduated Length Leaves is Given
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Verified Number of Graduated length leaves When Deflection at Load Point (Graduated-Length Leaves) is given
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Verified Number of Graduated length leaves When Force Taken by Graduated length Leaves is Given
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Verified Thickness of each Leaf Bending Stress in the Plate(Extra Full Length) is Given
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Verified Thickness of each Leaf When Bending Stress in the Plate is Given
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Verified Thickness of Each Leaf When Bending Stress on Graduated Length Leaves is Given
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Verified Thickness of Each Leaf When Bending Stress on Graduated Length Leaves is Given
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Verified Thickness of each Leaf When Deflection at the Load Point (Graduated Length Leaves) is Given
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Verified Width of Each Leaf When Bending Stress in the Plate is Given
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Verified Width of Each Leaf When Bending Stress in the Plate(Extra Full Length) is Given
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Verified Width of Each Leaf When Bending Stress on Graduated Length Leaves is Given
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Verified Width of Each Leaf When Deflection at the Load Point(Graduated Length Leaves) is Given
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5 More Multi-Leaf Spring Calculators
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Verified Current entering drain-source at boundary of the saturation and triode region of NMOS
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Verified Current entering drain-source at saturation region of NMOS
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Verified Current entering drain-source at saturation region of NMOS when effective voltage is given
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Verified Current entering drain-source in triode region of NMOS
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Verified Current entering drain-source in triode region of NMOS when effective voltage is given
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Verified Force Applied at the End of Spring
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Verified Force Applied at the End of the Spring When Pre-Load Required to Close the Gap is Given
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Verified Initial Nip in the Leaf Spring
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Verified Initial Pre-Load Required to Close the Gap
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Verified Length of Cantilever When Initial Nip of Leaf Spring is Given
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Verified Modulus of Elasticity When Initial Nip of the Spring is Given
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Verified Number of Full Length Leaves When Initial Pre-load Required to Close the Gap is Given
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Verified Number of Graduated length Leaves When Initial Pre-Load Required to Close the Gap is Given
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Verified Thickness of Each Leaf When Initial Nip of the Leaf Spring is Given
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Verified Total Number of Leaves When Pre-Load Required to Close the Gap is Given
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Verified Total Number of Springs When Initial Nip of the Leaf Spring is Given
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Verified Width of Each Leaf When Initial Nip of Leaf Spring is Given
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Created Load Current Using Losses (Nominal pi-method)
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Created Load Current Using Transmission Efficiency (Nominal pi-method)
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Created Losses (Nominal pi-method)
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Created Losses Using Sending End Power (Nominal pi-method)
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Created Losses Using Transmission Efficiency (Nominal pi-method)
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Created Receiving End Angle Using Sending End Power (Nominal pi-method)
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Created Receiving End Angle Using Transmission Efficiency (Nominal pi-method)
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Created Receiving End Current Using Sending End Power (Nominal pi-method)
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Created Receiving End Current Using Transmission Efficiency (Nominal pi-method)
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Created Receiving End Power Using Transmission Efficiency (Nominal pi-method)
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Created Receiving End Voltage Using Sending End Power (Nominal pi-method)
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Created Receiving End Voltage Using Transmission Efficiency (Nominal pi-method)
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Created Resistance Using Losses (Nominal pi-method)
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Created Resistance Using Transmission Efficiency (Nominal pi-method)
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Created Sending End Angle Using Transmission Efficiency (Nominal pi-method)
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Created Sending End Current Using Transmission Efficiency (Nominal pi-method)
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Created Sending End Power Using Transmission Efficiency (Nominal pi-method)
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Created Sending End Power Using Transmission Efficiency (Nominal pi-method)
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Created Sending End Voltage Using Transmission Efficiency (Nominal pi-method)
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Created Transmission Efficiency (Nominal pi-method)
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Created Capacitive Current (Nominal T-method)
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Created Capacitive Voltage (Nominal T-method)
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Created Capacitive Voltage Using Sending End Voltage (Nominal T-method)
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Created Impedance Using Capacitive Voltage (Nominal T-method)
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Created Impedance Using Sending End Voltage (Nominal T-method)
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Created Losses (Nominal T-method)
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Created Losses Using Sending End Power (Nominal T-method)
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Created Receiving End Angle Using Sending End Power (Nominal T-method)
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Created Receiving End Current (Nominal T-method)
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Created Receiving End Current Using Capacitive Voltage (Nominal T-method)
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Created Receiving End Current Using Losses (Nominal T-method)
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Created Receiving End Current Using Sending End Power (Nominal T-method)
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Created Receiving End Voltage Using Capacitive Voltage (Nominal T-method)
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Created Receiving End Voltage Using Sending End Power (Nominal T-method)
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Created Resistance Using Losses (Nominal T-method)
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Created Sending End Current (Nominal T-method)
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Created Sending End Current Using Capacitive Voltage (Nominal T-method)
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Created Sending End Current Using Losses (Nominal T-method)
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Created Sending End Voltage Using Capacitive Voltage (Nominal T-method)
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Created Number Of Turns In The Primary winding
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Created Number Of Turns In The Primary Winding When Voltage Transformation Ratio Is Given
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Created Number Of Turns In The Secondary Winding
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Created Number Of Turns In The Secondary Winding When Voltage Transformation Ratio Is Given
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Created a-phase Current (1OC)
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Created a-phase EMF Using Zero Sequence Impedance (1OC)
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Created b-phase Current
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Created c-phase Current (1OC)
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Created Negative Sequence Current Using Negative Sequence Impedance(1OC)
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Created Negative Sequence Current Using Positive Sequence Current (1OC)
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Created Negative Sequence Impedance Using Negative Sequence Voltage (1OC)
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Created Negative Sequence Potential Difference Using Potential Difference Between a-Phase (1OC)
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Created Negative Sequence Voltage Using Negative Sequence Impedance (1OC)
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Created Positive Sequence Current Using Negative Sequence Current(1OC)
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Created Positive Sequence Current Using Positive Sequence Voltage(1OC)
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Created Positive Sequence Current Using Zero Sequence Impedance (1OC)
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Created Positive Sequence Impedance Using Positive Sequence Voltage (1OC)
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Created Positive Sequence Potential Difference Using Potential Difference Between a-Phase (1OC)
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Created Positive Sequence Voltage Using Positive Sequence Impedance
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Created Potential Difference Between a-Phase (1OC)
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Created Potential Difference Between a-Phase Using Negative Sequence Potential Difference (1OC)
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Created Potential Difference Between a-Phase Using Positive Sequence Potential Difference (1OC)
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Created Potential Difference Between a-Phase Using Zero Sequence Potential Difference (1OC)
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Created Potential Difference Between b-Phase (1OC)
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Created Potential Difference Between c-Phase (1OC)
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Created Zero Sequence Current Using Positive Sequence Current(1OC)
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Created Zero Sequence Current Using Zero Sequence Voltage (1OC)
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Created Zero Sequence Current(1OC)
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Created Zero Sequence Impedance Using Zero Sequence Voltage (1OC)
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Created Zero Sequence Potential Difference Using Potential Difference Between a-Phase (1OC)
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Created Zero Sequence Voltage Using Zero Sequence Impedance (1OC)
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Verified Common-mode rejection ratio of the difference amplifiers
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16 More Operational Amplifiers Calculators
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Created Output Voltage When EMF Induced In Secondary Winding Is Given
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Verified Width of the Plane in Double Parallel Fillet Weld
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12 More Parallel Fillet Welds Calculators
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Verified Drain current in the saturation region of PMOS transistor
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Verified Drain current in the saturation region of PMOS transistor when Vov is given
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Verified Drain current in triode region of PMOS transistor
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Verified Drain current in triode region of PMOS transistor when VSD is given
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Verified Overall drain current of PMOS transistor
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Verified Overdrive voltage of PMOS
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Verified Transistor transconductance parameter of PMOS
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Verified Energy Of A Moving Particle Using Frequency
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Verified Energy Of A Moving Particle Using Wave Number
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Verified Energy Of A Moving Particle Using Wavelength
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Verified Frequency Of A Moving Particle
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2 More Planck Quantum Theory Calculators
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Verified Base current of PNP transistor when collector current is given
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Verified Base current of PNP transistor when common-base current gain is given
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Verified Base current of PNP transistor when emitter current is given
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Verified Base current of PNP transistor when saturation current is given
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Verified Collector current of PNP transistor
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Verified Collector current of PNP transistor when common-base current gain is given
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Verified Collector current of PNP transistor when common-emitter current gain
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Verified Emitter current when collector current is given
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Verified Emitter current when saturation current is given
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Verified Emitter current when the base current is given
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Verified Coefficient of Friction When Efficiency of Square Threaded Screw is Given
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Verified Core Diameter of Power Screw
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Verified Helix Angle of Thread
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Verified Mean Diameter of Power Screw
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Verified Nominal Diameter of Power Screw
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Verified Pitch of Power Screw
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Verified Pitch of the Screw When Mean Diameter is Given
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9 More Power Screws Calculators
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Created Average Load
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Created Complex Power When Current Is Given
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Created Complex Power When Voltage Is Given