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--- university:courses:electronics:electronics-lab-13a [25 Jan 2019 13:36] – add ltspice files Antoniu Miclaus
+++ university:courses:electronics:electronics-lab-13a [27 Jan 2021 22:36] – use wp> interwiki links Robin Getz
@@ Line 1: / Line 1: @@
-====== Activity 13A. Amplifier Output Stages ======
+====== Activity: Amplifier Output Stages ======
 ===== Objective: =====
@@ Line 36: / Line 36: @@
 ===== Procedure: =====
-The waveform generator, W1, should be configured for a 1 KHz sine wave with 6.0 volt amplitude peak amplitude and 0 offset. Using scope channel 1 to observe the input at W1 and scope channel 2 to observe the output of the amplifier at R<sub>L</sub>.
+The waveform generator, W1, should be configured for a 1 KHz sine wave with 6.0 volt amplitude peak-to-peak and 0 offset. Using scope channel 1 to observe the input at W1 and scope channel 2 to observe the output of the amplifier at R<sub>L</sub>.
 {{ :university:courses:electronics:a13a_f3_wf.png? |}}
 <WRAP centeralign> Figure 3 Push - Pull Output stage Waveforms </WRAP>
-Next, apply power and adjust the waveform generator so that W1 is a 100 Hz triangle wave with 0V offset and 3.0 V amplitude values. Use the oscilloscope in the x-y mode to observe the voltage-transfer curve of the circuit.
+Next, apply power and adjust the waveform generator so that W1 is a 100 Hz triangle wave with 0V offset and 3.0 V amplitude peak-to-peak. Use the oscilloscope in the x-y mode to observe the voltage-transfer curve of the circuit.
 {{ :university:courses:electronics:a13a_f4_tc.png?400 |}}
@@ Line 54: / Line 54: @@
 • Starting with the amplitude = 0 V, gradually increase it until you just begin to see a signal on scope channel 2 appear at the output. For what range of amplitude values of W1 can we say that both BJT's are essentially off? Confirm this by observing the voltages of the current-sensing resistances R<sub>1</sub> and R<sub>2</sub>.
-• Raise W1 to 6.0V amplitude value, and record the amplitude of the output waveform as well as the collector currents of the BJTs, which can be found via Ohm's law from the voltages across R<sub>1</sub> and R<sub>2</sub>, and justify your findings in terms of circuit operation and the given component values.
+• Raise W1 to 6.0V amplitude peak-to-peak value, and record the amplitude of the output waveform as well as the collector currents of the BJTs, which can be found via Ohm's law from the voltages across R<sub>1</sub> and R<sub>2</sub>, and justify your findings in terms of circuit operation and the given component values.
-• Repeat, but with W1 raised a 10.0V amplitude value; and comment.
+• Repeat, but with W1 raised a 10.0V amplitude peak-to-peak value; and comment.
 Simulate the circuit of figure 1 using QUCS, compare with your lab findings, and justify any differences.
@@ Line 80: / Line 80: @@
 ===== Procedure: =====
-The waveform generator, W1, should be configured for a 1 KHz sine wave with 6.0 volt amplitude peak amplitude and 0 offset. Using scope channel 1 to observe the input at W1 and scope channel 2 to observe the output of the amplifier at R<sub>L</sub>.
+The waveform generator, W1, should be configured for a 1 KHz sine wave with 6.0 volt amplitude peak-to-peak and 0 offset. Using scope channel 1 to observe the input at W1 and scope channel 2 to observe the output of the amplifier at R<sub>L</sub>.
 {{ :university:courses:electronics:a13a_f7_wf.png? |}}
@@ Line 112: / Line 112: @@
 ===== Procedure: =====
-The waveform generator, W1, should be configured for a 1 KHz sine wave with 6.0 volt amplitude peak amplitude and 0 offset. Using scope channel 1 to observe the input at W1 and scope channel 2 to observe the output of the amplifier at R<sub>L</sub>.
+The waveform generator, W1, should be configured for a 1 KHz sine wave with 6.0 volt amplitude peak-to-peak and 0 offset. Using scope channel 1 to observe the input at W1 and scope channel 2 to observe the output of the amplifier at R<sub>L</sub>.
 {{ :university:courses:electronics:a13a_f10_wf.png? |}}
@@ Line 118: / Line 118: @@
 ** Lab Resources:**
-  * LTSpice files: [[ https://minhaskamal.github.io/DownGit/#/home?url=https://github.com/analogdevicesinc/education_tools/tree/master/m2k/ltspice/amp_out_stg_ltspice | amp_out_stage_ltspice]]
+  * LTSpice files: [[downgit>education_tools/tree/master/m2k/ltspice/amp_out_stg_ltspice | amp_out_stage_ltspice]]
@@ Line 133: / Line 133: @@
 Simulate the circuit of figure 3 using LTSpice or ADIsimPE, compare with your lab findings, and justify any differences.
+<WRAP round download>
 **Resources:**
-  * Fritzing files: [[ https://minhaskamal.github.io/DownGit/#/home?url=https://github.com/analogdevicesinc/education_tools/tree/master/m2k/fritzing/output-stages | output_stages]]
+  * Fritzing files: [[downgit>education_tools/tree/master/m2k/fritzing/output-stages | output_stages]]
-  * LTspice files: [[ https://minhaskamal.github.io/DownGit/#/home?url=https://github.com/analogdevicesinc/education_tools/tree/master/m2k/ltspice/output_stages_ltspice | output_stages_ltspice ]]
+  * LTspice files: [[downgit>education_tools/tree/master/m2k/ltspice/output_stages_ltspice | output_stages_ltspice ]]
+</WRAP>
 ==== For Further reading: ====
-Output Stages [[http://www.analog.com/static/imported-files/tutorials/MT-207.pdf|(MT-207)]]\\
+Output Stages [[adi>static/imported-files/tutorials/MT-207.pdf|(MT-207)]]\\
-[[http://en.wikipedia.org/wiki/Push-pull_output|Push-Pull Outputs]]
+[[wp>Push-pull_output|Push-Pull Outputs]]

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