V-to-I and I-to-V Converters PDF

Summary

This document details voltage-to-current (V-to-I) and current-to-voltage (I-to-V) converters. It covers their basic circuits, operations, equations, and key features, such as high input impedance and low output impedance. The document also includes applications, including driving current-based loads and current sensing.

Full Transcript

1. Voltage-to-Current Converter (V-to-I Converter)

 Definition: A V-to-I converter converts an input voltage into a proportional
output current. It is commonly used to drive devices that require current as the
input, like LEDs, motors, and transducers.
 Basic Circuit:
o Op-Amp in Inverting Configuration: The input voltage is applied at the
inverting terminal of the Op-Amp, and the feedback loop contains a resistor
that controls the output current.
o The output current IoutI_{out}Iout is proportional to the input voltage
VinV_{in}Vin, and it flows through the load connected in series with the
output.
 Operation:
o The Op-Amp maintains a virtual ground at the inverting terminal, ensuring that
the current through the load is directly proportional to the input voltage.
o Output Current Equation: Iout=VinRI_{out} = \frac{V_{in}}{R}Iout=RVin
where RRR is the feedback resistor.
 Key Features:
o High Input Impedance: The input voltage is applied to the non-inverting
terminal, maintaining high input impedance.
o Low Output Impedance: The output is a low impedance current source.
 Applications:
o Driving current-based loads like LEDs, laser diodes, and actuators.
o Analog signal transmission over long distances using current.

2. Current-to-Voltage Converter (I-to-V Converter)

 Definition: An I-to-V converter converts an input current into a proportional
output voltage. It is widely used in sensor applications where the output of the
sensor is in the form of current (e.g., photodiodes, current transducers).
 Basic Circuit:
o Op-Amp in Inverting Configuration: The input current is applied to the
inverting terminal, and a feedback resistor converts the current into a voltage.
o The output voltage VoutV_{out}Vout is proportional to the input current
IinI_{in}Iin.
 Operation:
o The Op-Amp keeps the inverting terminal at a virtual ground. The input current
flows through the feedback resistor, developing a voltage across it.
o Output Voltage Equation: Vout=−Iin×RfV_{out} = - I_{in} \times R_fVout
=−Iin×Rf where RfR_fRf is the feedback resistor.
 Key Features:
o High Accuracy: Provides a precise voltage output proportional to the input
current.
o High Sensitivity: Especially useful in amplifying small currents, such as those
from photodiodes.
o Low Input Impedance: Ensures that the input current is accurately converted
without significant losses.
 Applications:
o Photodiode amplifiers (converting light-induced current into voltage).
o Sensing applications where output is in the form of current (e.g., current
transducers).
o Current measurement in electronic systems.

Comparison of V-to-I and I-to-V Converters:

Converte Input Output Op-Amp Key
r Type Configuratio Application
n s
Voltage- Voltag Proportiona Inverting with Driving
to- e l Current Load current-
Current Signal based loads
(V-to-I) (e.g., LEDs,
motors)
Current- Current Proportiona Inverting with Photodiode
to- Signal l Voltage Feedback amplifiers,
Voltage Resistor current
(I-to-V) sensing