Download Project 4 - Rensselaer Polytechnic Institute

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Electrical ballast wikipedia , lookup

Flip-flop (electronics) wikipedia , lookup

Buck converter wikipedia , lookup

Chirp spectrum wikipedia , lookup

Dynamic range compression wikipedia , lookup

Resistive opto-isolator wikipedia , lookup

Switched-mode power supply wikipedia , lookup

Metadyne wikipedia , lookup

Wien bridge oscillator wikipedia , lookup

Integrating ADC wikipedia , lookup

Electronic paper wikipedia , lookup

Electronic musical instrument wikipedia , lookup

Music technology (electronic and digital) wikipedia , lookup

Analog-to-digital converter wikipedia , lookup

Pulse-width modulation wikipedia , lookup

Oscilloscope history wikipedia , lookup

Electronic music wikipedia , lookup

Regenerative circuit wikipedia , lookup

Single-sideband modulation wikipedia , lookup

Electronic engineering wikipedia , lookup

Heterodyne wikipedia , lookup

Opto-isolator wikipedia , lookup

Transcript
Electronic Instrumentation
Project 4
•1. Optical Communications
•2. Initial Design
•3. PSpice Model
•4. Final Design
•5. Project Report
1. Optical Communications
5/23/2017
ENGR-4300 Electronic Instrumentation
2
Transmitting an audio signal using light
Transmitter Circuit
Receiver Circuit
5/23/2017
ENGR-4300 Electronic Instrumentation
3
Modulation
• Modulation is a way to encode an
electromagnetic signal so that it can be
transmitted and received.
• A carrier signal (constant) is changed
by the transmitter in some way based
on the information to be sent.
• The receiver then recreates the signal
by looking at how the carrier was
changed.
5/23/2017
ENGR-4300 Electronic Instrumentation
4
Amplitude Modulation
Frequency of carrier
remains constant.
Input signal alters
amplitude of carrier.
Higher input voltage
means higher carrier
amplitude.
http://cnyack.homestead.com/files/modulation/modam.htm
5/23/2017
ENGR-4300 Electronic Instrumentation
5
Frequency Modulation
Amplitude of carrier
remains constant.
Input signal alters
frequency of carrier.
Higher input voltage
means higher carrier
frequency.
http://cnyack.homestead.com/files/modulation/modfm.htm
5/23/2017
ENGR-4300 Electronic Instrumentation
6
Pulse Width Modulation
Period of carrier
remains constant.
Input signal alters duty
cycle and pulse width
of carrier.
Higher input voltage
means pulses with
longer pulse widths
and higher duty
cycles.
http://cnyack.homestead.com/files/modulation/modpwm.htm
5/23/2017
ENGR-4300 Electronic Instrumentation
7
Pulse Position Modulation
Pulse width of carrier
remains constant.
Input signal alters
period and duty cycle
of carrier.
Higher input voltage
means pulses with
longer periods and
lower duty cycles.
http://cnyack.homestead.com/files/modulation/modppm.htm
5/23/2017
ENGR-4300 Electronic Instrumentation
8
Pulse Frequency Modulation
Duty cycle of carrier
remains constant.
Input signal alters
pulse width and period
of carrier.
Higher input voltage
means pulses with
longer pulse widths
and longer periods.
5/23/2017
ENGR-4300 Electronic Instrumentation
9
2. Initial Design
transmitter
receiver
• The initial design for this project is a circuit
consisting of a transmitter and a receiver.
• The circuit is divided into functional blocks.
• Transmitter: Block A-B and Block B-C
• Transmission: Block C-D
• Receiver: Block D-E, Block E-F, Block F-G, and Block
G-H
• You will need to examine each block of the circuit.
5/23/2017
ENGR-4300 Electronic Instrumentation
10
Transmitter Circuit
Rpot
V1
2
4
5
6
7
27k
1k
5V
C8
4.7uF
C3
X1
TRIGGER
RESET OUTPUT
CONTROL
THRESHOLD
DISCHARGE
3
GND
R2
1
R3
VCC
8
100k
555D
330u
R19
.001uF
100ohms
C2
Function_Gen_1
LED
D1
0
5/23/2017
ENGR-4300 Electronic Instrumentation
11
Input and Modulated Output
Rpot
V1
2
4
5
6
7
27k
1k
5V
C8
4.7uF
C3
X1
TRIGGER
RESET OUTPUT
CONTROL
THRESHOLD
DISCHARGE
3
GND
R2
1
R3
VCC
8
100k
555D
330u
R19
.001uF
100ohms
C2
Function_Gen_1
LED
D1
0
5/23/2017
ENGR-4300 Electronic Instrumentation
12
Special Capacitors
Rpot
V1
2
4
5
6
7
27k
1k
5V
C8
4.7uF
C3
X1
TRIGGER
RESET OUTPUT
CONTROL
THRESHOLD
DISCHARGE
3
GND
R2
1
R3
VCC
8
100k
555D
330u
R19
.001uF
100ohms
C2
Function_Gen_1
LED
D1
Bypass Capacitor
(Low Pass Filter)
5/23/2017
0
ENGR-4300 Electronic Instrumentation
DC Blocking
Capacitor
(High Pass Filter)
13
Sample Input and Output
• When input is higher, pulses are longer
• When input is lower, pulses are shorter
5/23/2017
ENGR-4300 Electronic Instrumentation
14
Your signal is what?
The type of modulation this circuit creates is most
closely categorized as pulse frequency modulation.
But the pulse width is also modulated and we will use
that feature.
5/23/2017
ENGR-4300 Electronic Instrumentation
15
Sampling Frequency
• The pot (used as a variable resistor) controls
your sampling frequency
• Input frequency in audible range
• max range (20 - 20kHz)
• representative range (500 - 4kHz)
• Sampling frequency should be between
8kHz and 48kHz to reconstruct sound
• Input amplitude should not exceed 2Vp-p
• Function generator can provide 1.2Vp-p
5/23/2017
ENGR-4300 Electronic Instrumentation
16
Receiver Circuit
56k
Add a 100 Ohm resistor in series with the
speaker to avoid failures.
5/23/2017
ENGR-4300 Electronic Instrumentation
17
Receive Light Signal
56k
Add a 100 Ohm resistor in series with the
speaker to avoid failures.
5/23/2017
ENGR-4300 Electronic Instrumentation
18
Inverting Amplifier (Pre-Amp)
56k
Add a 100 Ohm resistor in series with the
speaker to avoid failures.
5/23/2017
ENGR-4300 Electronic Instrumentation
19
Audio Amplifier
56k
Add a 100 Ohm resistor in series with the
speaker to avoid failures.
5/23/2017
ENGR-4300 Electronic Instrumentation
20
Audio Amplifier Details
increases
gain 10X
(not needed)
386 audio
amplifier
high pass
filter
volume
Add a 100 Ohm resistor in series with the
speaker to avoid failures.
5/23/2017
ENGR-4300 Electronic Instrumentation
low pass filter
21
Special Capacitors
56k
Not needed
DC Blocking
Bypass
Capacitor Capacitor
5/23/2017
Add a 100 Ohm resistor in series with the
speaker to avoid failures.
ENGR-4300 Electronic Instrumentation
22
3. PSpice Model
• You will compare the performance of
your circuit to a PSpice model.
• The PSpice for the initial design will be
given to you.
• You will use the PSpice to help you
make decisions about how to create
your final design.
5/23/2017
ENGR-4300 Electronic Instrumentation
23
5/23/2017
ENGR-4300 Electronic Instrumentation
24
Comparing Output of Blocks
• Take pictures of the signal on each side of the
circuit block.
• A on channel 1 and B on channel 2
• B on channel 1 and C on channel 2
• Take all measurements relative to ground
• Does the block behave as expected?
• How does it compare to the PSpice output?
5/23/2017
ENGR-4300 Electronic Instrumentation
25
Comparing Output of Blocks
10V
“wide-angle” view
• Shows overall
shape and size
of input and
output
5V
0V
-5V
8.0ms
V(R1:1)
8.4ms
V(L1:2)
8.8ms
9.2ms
9.6ms
10.0ms
Time
1.0V
0V
-1.0V
8.301ms
V(R1:1)
8.400ms
V(L1:2)/10
8.500ms
8.600ms
8.700ms
8.799ms
“close-up” view
• Output divided
by 10
• Shows
sampling
frequency
• Shows shape
of samples
Time
5/23/2017
ENGR-4300 Electronic Instrumentation
26
4. Final Design
• The signal is reconstructed well enough by
the initial design that it will be audible.
• In order to improve the quality of the signal,
you will add an integrator, which will more
exactly reconstruct it.
• Types of integrators
• passive integrator (low pass filter)
• active integrator (op amp integrator circuit)
• You will then improve the signal further with a
smoothing capacitor.
5/23/2017
ENGR-4300 Electronic Instrumentation
27
Passive Integration
Vin
Vout
R1
500mV
E
C1
0
1
Vout 
Vin dt

RC
1
fC 
2RC
5/23/2017
250mV
0V
1.0Hz
V(R1:2)
10KHz
100MHz
Frequency
Integration works only
at high frequencies f >>fc.
Unfortunately,
your amplitude will also
decrease.
ENGR-4300 Electronic Instrumentation
28
Active Integration
F
500mV
E
250mV
0V
1.0Hz
V(R1:2)
10KHz
100MHz
Frequency
Vout
1

Vin dt

Ri C
1
fC 
2R f C
5/23/2017
• Integration works at f >>fc
• Your gain goes from -Rf/Ri to
-1/RiC
• The amplitude of your signal
will decrease or increase
depending on components
ENGR-4300 Electronic Instrumentation
29
Input at A vs. Output at H
10V
5V
0V
-5V
8.0ms
V(R1:1)
8.4ms
V(L1:2)
8.8ms
9.2ms
Before addition of integrator
9.6ms
10.0ms
Time
4.0V
2.0V
0V
-2.0V
8.0ms
V(V4:+)
8.4ms
V(L1:2)
8.8ms
9.2ms
After addition of integrator
9.6ms
10.0ms
Time
5/23/2017
ENGR-4300 Electronic Instrumentation
30
Effect of Smoothing Capacitor
D1
D1N4148
V
V
V1
VOFF = 0
VAMPL = 5v
FREQ = 1k
R1
C1
1k
5u
0
Recall what the smoothing capacitor did to the output of
the half wave rectifier.
5/23/2017
ENGR-4300 Electronic Instrumentation
31
Input at A vs. Output at H
4.0V
2.0V
0V
-2.0V
8.0ms
V(V4:+)
8.4ms
V(L1:2)
8.8ms
9.2ms
Before smoothing capacitor
9.6ms
10.0ms
9.6ms
10.0ms
Time
2.0V
0V
-2.0V
8.0ms
V(V4:+)
8.4ms
V(L1:2)
-v(L1:2)
8.8ms
9.2ms
After smoothing capacitor
Time
5/23/2017
ENGR-4300 Electronic Instrumentation
32
Project Packet
• Initial Data with Function Generator
•
•
•
•
•
PSpice
Mobile Studio plots from circuit
Brief Comparison
Block Description
For
• Blocks: A-B, A-C, A-D, A-E, A-F, A-G
• Overall System: A-H
• Initial Data with Audio
• Mobile Studio plots from circuit
• For E-F and A-H
5/23/2017
ENGR-4300 Electronic Instrumentation
33
Project Packet
• Final Data (integrator only) with Function
Generator
•
•
•
•
PSpice
Mobile Studio plots from circuit
Brief Comparison
For E-F and A-H
• Final Data (integrator and smoothing) PSpice
only
• PSpice
• Compare to without smoothing
• For E-F and A-H
5/23/2017
ENGR-4300 Electronic Instrumentation
34
Project Packet
• Final Data with Integrator (and possibly
Smoothing) with Audio
• Mobile Studio plots from circuit
• For E-F and A-H
• Extra Credit
• Mobile Studio picture of A-H with input from
function generator and integrated, smoothed
output. Indicate values of components and where
used.
5/23/2017
ENGR-4300 Electronic Instrumentation
35
Work in teams
• Put the transmitter on one protoboard and the
receiver on a second.
• One pair do the transmitter circuit
• This is the easier circuit, so maybe also start the PSpice
simulation.
• The other pair build the receiver circuit
• One report for the entire team
• Report is closer to an experiment report than a
project report
• See details in handout.
5/23/2017
ENGR-4300 Electronic Instrumentation
36