Receiver Front End Rise Time Calculator

↳

Electronics

Chemical Engineering

Civil

Electrical

Electronics and Instrumentation

Materials Science

Mechanical

Production Engineering

⤿

Transmission Measurements

C-V Actions of Optics Transmission

Fiber Optic Parameters

Optical Detectors

✖Receiver Bandwidth refers to the range of frequencies or the amount of data that a receiver can handle or process.ⓘ Receiver Bandwidth [B_RX]

+10%

-10%

✖Received Rise Time is the time taken for the output signal of the receiver to rise from a specified lower threshold to a specified upper threshold when exposed to a step-like input optical pulse.ⓘ Receiver Front End Rise Time [t_RX]

⎘ Copy

👎

Formula

✖

Receiver Front End Rise Time

Formula

`"t"_{"RX"} = 350/"B"_{"RX"}`

Example

`"15.90909s"=350/"22Hz"`

Calculator

LaTeX

Reset

👍

Download Electronics Formula PDF PDF Image

Receiver Front End Rise Time Solution

STEP 0: Pre-Calculation Summary

Formula Used

Received Rise Time = 350/Receiver Bandwidth
t_RX = 350/B_RX
This formula uses 2 Variables

Variables Used

Received Rise Time - (Measured in Second) - Received Rise Time is the time taken for the output signal of the receiver to rise from a specified lower threshold to a specified upper threshold when exposed to a step-like input optical pulse.
Receiver Bandwidth - (Measured in Hertz) - Receiver Bandwidth refers to the range of frequencies or the amount of data that a receiver can handle or process.

STEP 1: Convert Input(s) to Base Unit

Receiver Bandwidth: 22 Hertz --> 22 Hertz No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

t_RX = 350/B_RX --> 350/22

Evaluating ... ...

t_RX = 15.9090909090909

STEP 3: Convert Result to Output's Unit

15.9090909090909 Second --> No Conversion Required

FINAL ANSWER

15.9090909090909 ≈ 15.90909 Second <-- Received Rise Time

(Calculation completed in 00.004 seconds)

You are here -

Home » Engineering » Electronics » Fiber Optic Transmission » Transmission Measurements » Receiver Front End Rise Time

Credits

Created by Santhosh Yadav

Dayananda Sagar College Of Engineering (DSCE), Banglore

Santhosh Yadav has created this Calculator and 50+ more calculators!

Verified by Parminder Singh

Chandigarh University (CU), Punjab

Parminder Singh has verified this Calculator and 600+ more calculators!

< 20 Transmission Measurements Calculators

Time Constant of Calorimeter

Go Time Constant = (Time Instance 2-Time Instance 1)/(ln(Maximum Temperature Rise-Temperature At Time t1)-ln(Maximum Temperature Rise-Temperature At Time t2))

Optical Attenuation

Go Attenuation Per Unit Length = 10/(Length Of Cable-Cut Length)*log10(Photoreceiver Voltage At Cut Length/Photoreceiver Voltage At Full Length)

Optical Return Loss

Go Optical Return Loss = 10*log10((Output Power*Reflected Power)/(Source Power*(Power at Port 2-Power at Port 4)))

Guided Modes Number

Go Guided Modes Number = ((pi*Radius of Core)/Wavelength of Light)^2*(Refractive Index of Core^2-Refractive Index of Cladding^2)

Bit Error Rate given SNR

Go Bit Error Rate = (1/sqrt(2*pi))*(exp(-Signal to Noise Ratio of Photodetector^2/2))/Signal to Noise Ratio of Photodetector

Fiber Rise Time

Go Fiber Rise Time = modulus(Chromatic Dispersion Coefficient)*Length Of Cable*Half Power Spectral Width

Ideal Etalon Transmission

Go Transmission of Etalon = (1+(4*Reflectivity)/(1-Reflectivity)^2*sin(Single-Pass Phase Shift/2)^2)^-1

3dB Pulse Broadening

Go 3dB Pulse Broadening = sqrt(Optical Output Pulse^2-Optical Input Pulse^2)/(Length Of Cable)

Absorption Loss

Go Absorption Loss = (Thermal Capacity*Maximum Temperature Rise)/(Optical Power*Time Constant)

Free Spectral Range of Etalon

Go Free Spectral Range Wavelength = Wavelength of Light^2/(2*Refractive Index of Core*Slab Thickness)

Scattering Loss

Go Scattering Loss = ((4.343*10^5)/Fiber Length)*(Constant Output Optical Power/Output Optical Power)

Refractive Index Difference

Go Difference Refractive Index = (Fringe Displacements Number*Wavelength of Light)/Slab Thickness

Pulse Spreading Time

Go Pulse Spreading Time = Polarisation Mode Dispersion Coefficient*sqrt(Length Of Cable)

Finesse of Etalon

Go Finesse = (pi*sqrt(Reflectivity))/(1-Reflectivity)

Power Penalty

Go Power Penalty = -10*log10((Extinction Ratio-1)/(Extinction Ratio+1))

Relative Attenuation

Go Relative Attenuation = 10*log10(Total Power/Spectral Power)

Bend Attenuation

Go Bend Attenuation = 10*log10(Total Power/Small Power)

Modal Rise Time

Go Modal Rise Time = (440*Length Of Cable)/Modal Dispersion Bandwidth

Optical Modulation Index

Go Modulation Index = Incident Power/Optical Power at Bias Current

Receiver Front End Rise Time

Go Received Rise Time = 350/Receiver Bandwidth

Receiver Front End Rise Time Formula

Received Rise Time = 350/Receiver Bandwidth
t_RX = 350/B_RX

Why is Receiver Front End Rise Time needed?

Receiver front end rise time is needed in optical systems to ensure that the receiver can quickly respond to fast changes in incoming optical signals. A fast rise time allows the receiver to accurately detect and reproduce optical pulses with sharp edges, making it essential for high-speed data transmission in applications like fiber-optic communication.

How to Calculate Receiver Front End Rise Time?

Receiver Front End Rise Time calculator uses Received Rise Time = 350/Receiver Bandwidth to calculate the Received Rise Time, Receiver Front End Rise Time refers to a characteristic of the front-end electronics of a photodetector or receiver system. The rise time is the time it takes for the output signal of the photodetector or receiver to rise from a specified lower threshold to a specified upper threshold when exposed to a step-like input optical pulse. Received Rise Time is denoted by t_RX symbol.

How to calculate Receiver Front End Rise Time using this online calculator? To use this online calculator for Receiver Front End Rise Time, enter Receiver Bandwidth (B_RX) and hit the calculate button. Here is how the Receiver Front End Rise Time calculation can be explained with given input values -> 15.90909 = 350/22.

FAQ

What is Receiver Front End Rise Time?

Receiver Front End Rise Time refers to a characteristic of the front-end electronics of a photodetector or receiver system. The rise time is the time it takes for the output signal of the photodetector or receiver to rise from a specified lower threshold to a specified upper threshold when exposed to a step-like input optical pulse and is represented as t_RX = 350/B_RX or Received Rise Time = 350/Receiver Bandwidth. Receiver Bandwidth refers to the range of frequencies or the amount of data that a receiver can handle or process.

How to calculate Receiver Front End Rise Time?

Receiver Front End Rise Time refers to a characteristic of the front-end electronics of a photodetector or receiver system. The rise time is the time it takes for the output signal of the photodetector or receiver to rise from a specified lower threshold to a specified upper threshold when exposed to a step-like input optical pulse is calculated using Received Rise Time = 350/Receiver Bandwidth. To calculate Receiver Front End Rise Time, you need Receiver Bandwidth (B_RX). With our tool, you need to enter the respective value for Receiver Bandwidth and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

Home

FREE PDFs

🔍 Search