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Transcript
EENG 1920 Chapter 5
System Design I:
Functional Decomposition
1
Motivation
Team of engineers who build a system need:
• An abstraction of the system
• An unambiguous communication medium
• A way to describe the subsystems
– Inputs
– Outputs
– Behavior
• Functional Decomposition
– Function – transformation from inputs to outputs
– Decomposition – reduce to constituent parts
2
Bottom Up Design
• Given constituent parts
• Develop a working system
– Build modules to accomplish specific tasks
– Integrate modules together into working system
• For example
– Given a supply AND, OR and NOT gates.
– Build a computer
• Pros
– Leads to efficient subsystem
• Cons
– Complexity is difficult to manage
– Little thought to designing reusable modules
– Redesign cycles
3
Top Down Design
• Given the specification of a system
• Develop a working system
– Divide the problem into abstract modules
– Reiterate until constituent parts are reached
• Pros
– Highly predictable design cycle
– Efficient division of labor
• Cons
– More time spent in planning
4
Functional Decomposition
• Recursively divide and conquer
– Split a module into several sub-modules
– Define the input, output, and behavior
– Stop when you reach realizable components
Determine Level 0
functional
requirements
N=1
Determine architecture and
functional requirements for
modules at Level N
At the detailed
design level?
Yes
DONE
No
N=N+1
5
Guidance
•
•
•
•
•
•
•
•
•
•
•
The design process is iterative
Upfront time saves redesign time later
Sub-modules should have similar complexity
Precise input, output, and behavior specifications
Look for innovation
Don’t decompose ad infinitium
Use suitable abstraction to describe sub-modules
Look at how it has been done before
Use existing technology
Keep it simple
Communicate results
6
Application Domains
• Electronics Design
• Digital Design
• Software Design
7
Example 1
The audio amplifier system must:
• Accept an audio input signal source with a
maximum input voltage of 0.5V peak.
• Have adjustable volume control between zero
volume and the maximum volume level.
• Deliver a maximum of 50W to an 8 speaker.
• Be powered by a standard 120V 60Hz AC outlet.
8
Level 0
Module
Audio Power Amplifier
Inputs
Audio input signal: 0.5V peak.
Power: 120 volts AC rms, 60Hz.
User volume control: variable control.
Outputs
Audio output signal: ?V peak value.
Functionality Amplify the input signal to produce a 50W
maximum output signal. The amplification
should have variable user control. The
output volume should be variable between
no volume and a maximum volume level.
audio input signal
Audio Power
Amplifier
audio output signal
power, 120 VAC
9
Level 1
Audio Amplifier Design
audio input
signal
buffered
input
Buffer Amplifier
High Gain Amplifier
voltage
amplified
signal
Power Output Stage
audio output
signal
DC voltages
Power Supply
power, 120 VAC
10
Level 1.1 Buffer Amplifier
Module
Buffer Amplifier
Inputs
- Audio input signal: 0.5V peak.
- Power:  25V DC.
Outputs
- Audio signal: 0.5V peak.
Functionality
Buffer the input signal and provide unity voltage
gain. It should have an input resistance >1M
and an output resistance <100.
11
Level 1.2 High Gain Amplifier
Module
High Gain Amplifier
Inputs
- Audio input signal: 0.5V peak.
- User volume control: variable control.
- Power:  25V DC
Outputs
- Audio signal: 20V peak.
Functionality
Provide an adjustable voltage gain, between 1 and
40. It should have an input resistance >100k
and an output resistance <100.
12
Example 2
The Thermometer system must
• Measure temperature between 0 and 200C.
• Have an accuracy of 0.4% of full scale.
• Display the temperature digitally, including one digit
beyond the decimal point.
• Be powered by a standard 120V 60Hz AC outlet.
• Use an RTD (thermal resistive device) that has an
accuracy of 0.55C over the range. The resistance of
the RTD varies linearly with temperature from 100Ω at
0C to 178Ω at 200C.
13
Level 0
Ambient
Temperature
Power,
120 VAC
Digital Thermometer
Digital
Temperature
Display
14
Level 0
Module
Digital Thermometer
Inputs
- Ambient temperature: 0-200C.
- Power: 120V AC power.
Outputs
- Digital temperature display: A four digit
display, including one digit beyond the
decimal point.
Functionali Displays temperature on digital readout with
ty
an accuracy of 0.4% of full scale.
15
Level 1
BCD0
b0
Ambient
Temperature
Temperature
Conversion Unit
VT
Analog to Digital
Converter
b1
.
.
.
bN-1
Binary Coded
Decimal (BCD)
Conversion Unit
BCD1
BCD2
7-Segment LED
Driver
BCD3
+/- x V DC
Power,
120 VAC
Power Supply
,
16
Level 1.1 Temperature Conversion Unit
Module
Temperature Conversion Unit
Inputs
- Ambient temperature: 0-200C.
- Power: ?V DC (to power the electronics).
Outputs
- VT: temperature proportional voltage. VT=
αT, and ranges from ? to ?V.
Functionali Produces an output voltage that is linearly
proportional to temperature. It must achieve
ty
an accuracy of ?%.
17
Level 1.2 A/D Converter
A/D Converter
Module
Inputs
- VT: voltage proportional to temperature that
ranges from ? to ?V.
- Power: ?V DC.
Outputs
- bN-1 -b0: ?-bit binary representation of VT.
Functionali Converts analog input to binary digital output.
ty
18
Coupling In Design
• Coupling describes a particular individual
module’s dependence upon the
interconnectivity of various modules for
proper functionality. A module can be
loosely coupled or tightly coupled.
19
Coupling In Design
•
•
•
•
•
•
Loosely Coupled
The maximum degree of impact one module can
have is limited
May allow for continued functionality upon
module failures
Maximizes the cohesion of a design
Allows for independent testing of modules
Tightly Coupled
Better performance (i.e. software)
Quicker solutions (not necessarily better)
20
Cohesion
• What is cohesion?
– How focused is the module
• Phenomena of highly cohesive systems
– Easy to test modules independently
– Simple (non-existent) control interface
• Phenomena of low cohesive systems
– Less reuse of modules
21
Chapter 5 Homework
1.
2.
Describe the differences between bottom-up and top-down design.
Develop a Level 0 diagram and table for an audio graphic
equalizer. A graphic equalizer decomposes an audio signal into
component frequencies bands, allows the user to apply
amplification to each individual band, and recombines the
component signals.
a. The system must Accept an audio input signal source, with a
source resistance of 1000Ω and a maximum input voltage of
1V peak-to-peak.
b. Have an adjustable volume control.
c. Deliver a maximum of 40W to an 8Ω speaker.
d. Have four frequency bands into which the audio is
decomposed (you select the frequency ranges).
22
Chapter 5 Homework Continued
3. Define coupling in a design.
4. What is cohesion?
23