Differences

This shows you the differences between two versions of the page.

--- university:courses:electronics:electronics-lab-variable-gain-amplifier [26 Mar 2018 12:09] – add Variable Gain Inverting Amplifier using potetiometer Antoniu Miclaus
+++ university:courses:electronics:electronics-lab-variable-gain-amplifier [23 Aug 2019 15:14] – Antoniu Miclaus
@@ Line 26: / Line 26: @@
 Consider the circuit schematic presented in Figure 1.
-<WRAP centeralign> {{:university:courses:electronics:var_gain_amp_crl-sch.png|}} </WRAP>
+<WRAP centeralign> {{ :university:courses:electronics:vctrl_amp_transistor.png|}} </WRAP>
 <WRAP centeralign> Figure 1. Voltage control using transistor </WRAP>
@@ Line 42: / Line 42: @@
 ==== Procedure ====
-Use the first waveform generator as source Vin to provide a 2V amplitude, 1 kHz sine wave excitation to the circuit. Use the second waveform generator for controlling the transistor, providing a 2V amplitude, 1Hz square wave excitation. Supply the op amp to +/- 5V from the power supply. Configure the scope so that the input signal is displayed on channel 1 and the output signal is displayed on channel 2.
+Use the first waveform generator as source Vin to provide a 2V amplitude peak-to-peak, 1 kHz sine wave excitation to the circuit. Use the second waveform generator for controlling the transistor, providing a 2V amplitude, 1Hz square wave excitation. Supply the op amp to +/- 5V from the power supply. Configure the scope so that the input signal is displayed on channel 1 and the output signal is displayed on channel 2.
 An animated plot is presented in Figure 3.
@@ Line 58: / Line 58: @@
 Consider the circuit schematic presented in Figure 4.
-<WRAP centeralign> {{:university:courses:electronics:var_gain_amp_pot2-sch.png?500|}} </WRAP>
+<WRAP centeralign> {{ :university:courses:electronics:var_g_invert_amp_pot.png|}} </WRAP>
 <WRAP centeralign> Figure 4. Variable Gain Inverting Amplifier using potetiometer </WRAP>
@@ Line 74: / Line 74: @@
 ==== Procedure ====
-Use the first waveform generator as source Vin to provide a 2V amplitude, 1 kHz sine wave excitation to the circuit.  Supply the op amp to +/- 5V from the power supply. Configure the scope so that the input signal is displayed on channel 1 and the output signal is displayed on channel 2.
+Use the first waveform generator as source Vin to provide a 2V amplitude peak-to-peak, 1 kHz sine wave excitation to the circuit.  Supply the op amp to +/- 5V from the power supply. Configure the scope so that the input signal is displayed on channel 1 and the output signal is displayed on channel 2.
-An animated plot is presented in Figure 6.
+By varying the value of the potentiometer, an animated plot is presented in Figure 6.
 <WRAP centeralign> {{:university:courses:electronics:var_gain_amp_pot2-wav.gif|}} </WRAP>
 <WRAP centeralign> Figure 6. Variable Gain Inverting Amplifier using potetiometer - waveforms </WRAP>
+Using this type of configuration, the output is inverted and amplified based on the feedback resistance value.
+===== Variable Gain Inverting/Non-Inverting Amplifier using potetiometer =====
+==== Background ====
+Consider the circuit schematic presented in Figure 7.
+<WRAP centeralign> {{ :university:courses:electronics:var_gain_inv_noninv.png|}} </WRAP>
+<WRAP centeralign> Figure 7. Variable Gain Inverting/Non-Inverting Amplifier using potetiometer </WRAP>
+In this amplifier configuration a potentiometer is used to control manually the output voltage, being able to invert the input by adjusting properly the potentiometer.
+==== Hardware Setup ====
+Build the following breadboard circuit for the voltage-controlled amplifier using transistors.
+<WRAP centeralign> {{:university:courses:electronics:var_gain_amp_pot-bb.png|}} </WRAP>
+<WRAP centeralign> Figure 8. Variable Gain Inverting/Non-Inverting Amplifier using potetiometer - breadboard circuit </WRAP>
+==== Procedure ====
+Use the first waveform generator as source Vin to provide a 2V amplitude peak-to-peak, 1 kHz sine wave excitation to the circuit.  Supply the op amp to +/- 5V from the power supply. Configure the scope so that the input signal is displayed on channel 1 and the output signal is displayed on channel 2.
+By varying the value of the potentiometer, an animated plot is presented in Figure 9.
+<WRAP centeralign> {{:university:courses:electronics:var_gain_amp_pot-wav.gif|}} </WRAP>
+<WRAP centeralign> Figure 9. Variable Gain Inverting/Non-Inverting Amplifier using potentiometer - waveforms </WRAP>
+Using this configuration, the output is amplified varying between +-Vin.
+===== Questions =====
+. Which are the gain values for each of the circuits used in this lab activity?
+. Based on the input signals and the computed gains, which are the expected output values? Compute and compare them with the measured values.
+. Considering the circuit in Figure 7, how can you increase the output range above +-Vin?
+===== Further Reading =====
+<WRAP round download>
+**Lab Resources:**
+  * Fritzing files: [[ https://minhaskamal.github.io/DownGit/#/home?url=https://github.com/analogdevicesinc/education_tools/tree/master/m2k/fritzing/var_gain_amp_bb | var_gain_amp_bb]]
+  * LTspice files: [[ https://minhaskamal.github.io/DownGit/#/home?url=https://github.com/analogdevicesinc/education_tools/tree/master/m2k/ltspice/var_gain_amp_ltspice | var_gain_amp_ltspice]]
+</WRAP>
+Some additional resources:
+  * [[http://www.analog.com/en/analog-dialogue/articles/x-amp-45-db-500-mhz-variable-gain-amplifier.html|X-Amp™, A New 45-dB, 500-MHz Variable-Gain Amplifier (VGA) Simplifies Adaptive Receiver Designs]]
+  * [[http://www.analog.com/en/analog-dialogue/articles/reinvent-the-signal-generator.html|Two New Devices Help Reinvent the Signal Generator]]
+**Return to Lab Activity [[university:courses:electronics:labs|Table of Contents]]**

Wiki

Analog Devices Wiki

Differences

Analog Devices Wiki

Differences

Page Tools