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Title: Circuit Protection and Tariffs
Description: Utilisation of Electrical Energy (UofEE) - Assignment 3. Construction and operation of circuit over-current protection devices and high power circuit breakers. Construction and operation. of ELCB and RCD devices. Definition of energy tariffs - two part structure. Effect of Power Factor on tariff Grade received: DISTINCTION Tutor: Mark Nailis Institute: Middlesbrough College Programme: Higher National Certificate (HNC) in Electrical and Electronic Engineering
Description: Utilisation of Electrical Energy (UofEE) - Assignment 3. Construction and operation of circuit over-current protection devices and high power circuit breakers. Construction and operation. of ELCB and RCD devices. Definition of energy tariffs - two part structure. Effect of Power Factor on tariff Grade received: DISTINCTION Tutor: Mark Nailis Institute: Middlesbrough College Programme: Higher National Certificate (HNC) in Electrical and Electronic Engineering
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HNC Electrical and Electronic Engineering
Year One - 2013/14
Module: Digital & Analogue Devices
Logic
Families
Keith A
...
Hudson
2
Digital & Analogue Devices
13 April, 2014
Contents
1
Logic Families (Task 1)
...
1
1
...
10
1
...
8
TTL vs CMOS
...
13
2
...
13
2
...
1
Voltage Comparison
...
1
...
14
2
...
3
Fan-Out
...
2
CMOS Driving TTL
...
2
...
15
2
...
2
Current Comparison
...
2
...
17
2
...
18
Combinational Logic (Task 2)
...
1
Mixed Logic
...
2
NAND Only Logic
...
3
Optimised NAND Only Logic
...
4
Why NAND Only Logic?
...
35
5
Combinational / Sequential Logic (Task 4)
...
49
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
7
Figure 2: I/O voltage levels for standard 74XX TTL series
...
9
Figure 4: Use of a pull-up resistor
...
18
Figure 6: Low voltage output driving high voltage Loads
...
19
Figure 8: I/P '0000' O/P '0'
...
21
Figure 10: I/P '0010' O/P '0'
...
21
Figure 12: I/P '0100' O/P '0'
...
22
Figure 14: I/P '0110' O/P '0'
...
22
Figure 16: I/P '1000' O/P '1'
...
23
Figure 18: I/P '1010' O/P '1'
...
23
Figure 20: I/P '1100' O/P '0'
...
24
Figure 22: I/P '1110' O/P '0'
...
24
Figure 24: I/P '0000' O/P '0'
...
25
Figure 26: I/P '0010' O/P '0'
...
26
Figure 28: I/P '0100' O/P '0'
...
26
Figure 30: I/P '0110' O/P '0'
...
27
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
27
Figure 33: I/P '1001' O/P '1'
...
27
Figure 35: I/P '1011' O/P '1'
...
28
Figure 37: I/P '1101' O/P '1'
...
28
Figure 39: I/P '1111' O/P '0'
...
30
Figure 41: I/P '0001' O/P '1'
...
30
Figure 43: I/P '0011' O/P '0'
...
31
Figure 45: I/P '0101' O/P '1'
...
31
Figure 47: I/P '0111' O/P '0'
...
32
Figure 49: I/P '1001' O/P '1'
...
32
Figure 51: I/P '1011' O/P '1'
...
33
Figure 53: I/P '1101' O/P '1'
...
33
Figure 55: I/P '1111' O/P '0'
...
35
Figure 57: LSB
...
36
Figure 58: LSB
...
36
Figure 59: LSB
...
36
Figure 60: LSB
...
37
Figure 61: LSB
...
37
Figure 62: LSB
...
37
Figure 63: LSB
...
37
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
MSB '1110' ==> '7'
...
MSB '0001' ==> '8'
...
MSB '1001' ==> '9'
...
MSB '0101' ==> 'A' (10)
...
MSB '1101' ==> 'b' (11)
...
MSB '0011' ==> 'C' (12)
...
MSB '1011' ==> '0' (13)
...
MSB '0111' ==> 'E' (14)
...
MSB '1111' ==> '0' (F)
...
MSB '0000' ==> '0' back to the start
...
Adapted from (Tangient LLC, 2014)
...
MSB '0000' ==> '0'
...
MSB '1000' ==> '1'
...
MSB '0100' ==> '2'
...
MSB '1100' ==> '3'
...
MSB '0010' ==> '4'
...
MSB '1010' ==> '5'
...
MSB '0110' ==> '6'
...
MSB '1110' ==> '7'
...
MSB '0001' ==> '8'
...
MSB '1001' ==> '9'
...
MSB '0000' ==> '0' Back to the start
...
Adapted from (Tangient LLC, 2014)
...
3 Logic-1
...
Hudson
6
Digital & Analogue Devices
13 April, 2014
Tables
Table 1: TTL chip families
...
10
Table 3: Advantages and disadvantages of TTL and CMOS
...
11
Table 5: Electrical characteristics
...
13
Table 7: TTL o/p to CMOS i/p - current comparison
...
14
Table 9: CMOS o/p to TTL i/p - voltage comparison
...
16
Table 11: Fan-out CMOS driving TTL β High level β1β
...
17
Table 13: F = A
...
D
...
42
Table 15: Karnaugh Map
...
Hudson
7
Digital & Analogue Devices
13 April, 2014
1 Logic Families
(Task 1)
Figure 1: Different Logic Families (Nailis, 2014)
Logic gates are built using transistors
...
The CMOS family of logic gates is created by connecting NMOS and PMOS transistors
...
Hudson
8
Digital & Analogue Devices
13 April, 2014
1
...
Hudson
9
Digital & Analogue Devices
13 April, 2014
Figure 2 shows how noise margin are calculated
...
e
...
Figure 3: Propagation Delays
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
2 Complementary Metal-Oxide-Semiconductor (CMOS)
Table 2: CMOS chip families
Chip family
Description
Acronym
4000
Original CMOS
40H00
High Speed CMOS
(Slower than LS TTL)
74C00
CMOS
...
Pin compatible
...
Greater noise immunity
...
3 TTL vs CMOS
Table 3: Advantages and disadvantages of TTL and CMOS
Family
TTL
CMOS
Advantages
More robust β less susceptible to static damage
Lowest power consumption
Most common logic family today
Used in all PC processor chips
HNC Electrical and Electronic Engineering
Disadvantages
Uses more power than CMOS
Susceptible to damage by static and voltage
spikes
Year One: 2013/14
Keith A
...
supply voltage
π πΆπΆ(πππ₯)
5
...
25V
5
...
0V
5
...
supply voltage
π πΆπΆ(πππ)
4
...
75V
4
...
0V
4
...
logic-1 output voltage
π ππ»(πππ)
2
...
7V
2
...
95V
4
...
9V
Min
...
0V
2
...
0V
3
...
5V
2
...
4V
0
...
5V
1
...
4V
2
...
logic-0 output voltage
π ππΏ(πππ₯)
0
...
5V
0
...
05V
0
...
1V
Max
...
8V
0
...
8V
1
...
0V
0
...
4V
0
...
3V
1
...
9V
0
...
output current (logic-1)
πΌ ππ»(πππ₯)
-0
...
4mA
-0
...
4mA
4mA
4mA
Max
...
04mA
0
...
02mA
1ΞΌA
1ΞΌA
1ΞΌA
10
20
20
400
4000
4000
Fan-out (logic-1)
π=
πΌ ππ»(πππ₯)
πΌ πΌπ»(πππ₯)
Max
...
4mA
4mA
4mA
Max
...
6mA
-0
...
1mA
1ΞΌA
1ΞΌA
1ΞΌA
10
11
40
400
4000
4000
Fan-out (logic-0)
π=
πΌ ππΏ(πππ₯)
πΌ πΌπΏ(πππ₯)
(Note: based on a 5V supply, where not stated)
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
Hudson
Digital & Analogue Devices
13 April, 2014
13
2 TTL and CMOS Interoperability
2
...
e
...
)
2
...
1 Voltage Comparison
Table 6: TTL o/p to CMOS i/p - voltage comparison
TTL Output
CMOS Input
π½ πΆπ―(π΄π°π΅)
Series
π½ π°π―(π΄π°π΅)
Comments
Series
5
...
0V
3
...
5V
74AHC Pull-up resistor required to use these
4000/74HC/74AC CMOS devices
...
0V
74ALS
74LS/74AS
74
2
...
5V
2
...
0V
2
...
65V
1
...
0V
74AHC
4000B/74AC
π ππΏ(ππ΄π) β€ ππΌπΏ(ππ΄π) so the β0β voltage
1
...
8V 74HCT/74ACT/74AHCT
74LS/74AS/74ALS 0
...
4V
0
...
In order to use
4000, 74HC, 74AC and 74AHC CMOS chips we must use a pull-up resistor (see Figure 4)
...
Hudson
Digital & Analogue Devices
13 April, 2014
14
Figure 4: Use of a pull-up resistor
2
...
2 Current Comparison
Table 7: TTL o/p to CMOS i/p - current comparison
TTL Output
Series
74ALS
74AS
74F
74/74LS
π° πΆπ―(π΄π¨πΏ)
400mA
2
...
0mA
0
...
2
...
3 Fan-Out
Table 8: Fan-out TTL driving CMOS
β1β π =
πππΏ πΌ ππ»(πππ₯)
πΆπππ πΌ πΌπ»(πππ₯)
=
0
...
I
...
one TTL device could drive up to 400
CMOS devices
...
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
2 CMOS Driving TTL
(I
...
CMOS output to TTL input
...
2
...
95V
4
...
4V
Series
5
...
0V
π ππ»(ππΌπ) β₯ ππΌπ»(ππΌπ) so the β1β
voltage is compatible
74AHCT
3
...
0V
2
...
0V 74/74LS/74AS/74ALS
1
...
8V 74/74LS/74AS/74ALS
0
...
1V
4000B
0
...
0V
CMOS Output
π½ π°π³(π΄π¨πΏ)
Series
TTL Input
Comments
As Table 9 shows all the CMOS chips are voltage compatible with all of the TTL chips
...
Hudson
16
Digital & Analogue Devices
13 April, 2014
2
...
2 Current Comparison
Table 10: CMOS o/p to TTL i/p - current comparison
CMOS Output
Series
74AC/74ACT
74AHC/74AHCT
74HC/74HCT
4000B
π° πΆπ―(π΄π¨πΏ)
24
...
0mA
4
...
4mA
TTL Input
π° π°π―(π΄π¨πΏ)
24
...
0mA
4
...
4mA
π° πΆπ³(π΄π¨πΏ)
CMOS Output
74
74F
74AS
74LS
100ΞΌA
4000B
1
...
6mA
0
...
4mA
74ALS
π° π°π³(π΄π¨πΏ)
Series
TTL Input
For 4000B CMOS chips
πΌ ππΏ(ππ΄π) β₯ πΌ πΌπΏ(ππ΄π) so the β0β
current is compatible for these TTL chips
Comments
As Table 10 shows all (but the 4000B) CMOS chips are current compatible with all of the TTL chips
...
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
2
...
04
0
...
02
0
...
02
74AC/74ACT
24
600
1200
1200
1200
1200
74AHC/74AHCT
8
200
400
400
400
400
74HC/74HCT
4
100
200
200
200
200
4000B
0
...
6
0
...
5
0
...
1
24
15
40
48
60
240
8
5
13
16
20
80
4
2
6
8
10
40
0
...
Note: 4000B CMOS chip cannot directly drive any of the following TTL chips: 74, 74F, 74AS
...
Hudson
18
Digital & Analogue Devices
13 April, 2014
2
...
The input to the buffer should match the output of the driver chip
...
A buffer can also be used to match voltage levels
...
Figure 6: Low voltage output driving high voltage Loads
Figure 6 shows the use of a voltage level translator buffer to drive a high voltage load from a low voltage
driver
...
Hudson
19
Digital & Analogue Devices
13 April, 2014
Figure 7: High-voltage o/p driving a low-voltage load
Figure 7 shows a low voltage buffer which can tolerant a 5V inputs as an interface to a low voltage load
from a high voltage driver
...
Hudson
Digital & Analogue Devices
13 April, 2014
20
3 Combinational Logic
(Task 2)
Table 13: π = π¨
...
B
C
C
...
B + C
...
1 Mixed Logic
Error! Reference source not found
...
The
circuit is constructed using two NOT gates, two AND and one NOT gate
...
to Figure 23 shows the output value for all permutations of the input
conditions
...
Hudson
21
Digital & Analogue Devices
13 April, 2014
Figure 9: I/P '0001' O/P '1'
Figure 10: I/P '0010' O/P '0'
Figure 11: I/P '0011' O/P '0'
Figure 12: I/P '0100' O/P '0'
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
Hudson
23
Digital & Analogue Devices
13 April, 2014
Figure 17: I/P '1001' O/P '1'
Figure 18: I/P '1010' O/P '1'
Figure 19: I/P '1011' O/P '1'
Figure 20: I/P '1100' O/P '0'
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
Hudson
25
Digital & Analogue Devices
13 April, 2014
3
...
The circuit is constructed using
NAND gates only
...
)
Figure 24: I/P '0000' O/P '0'
Figure 25: I/P '0001' O/P '1'
Figure 26: I/P '0010' O/P '0'
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
Hudson
27
Digital & Analogue Devices
13 April, 2014
Figure 31: I/P '0111' O/P '0'
Figure 32: I/P '1000' O/P '1'
Figure 33: I/P '1001' O/P '1'
Figure 34: I/P '1010' O/P '1'
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
Hudson
29
Digital & Analogue Devices
13 April, 2014
Figure 39: I/P '1111' O/P '0'
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
3 Optimised NAND Only Logic
Figure 40 to Figure 55 show the circuit for the truth table (see Table 13)
...
Figure 40: I/P '0000' O/P '0'
Figure 41: I/P '0001' O/P '1'
Figure 42: I/P '0010' O/P '0'
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
Hudson
32
Digital & Analogue Devices
13 April, 2014
Figure 47: I/P '0111' O/P '0'
Figure 48: I/P '1000' O/P '1'
Figure 49: I/P '1001' O/P '1'
Figure 50: I/P '1010' O/P '1'
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
Hudson
34
Digital & Analogue Devices
13 April, 2014
Figure 55: I/P '1111' O/P '0'
3
...
The change to NAND-only logic has not affected the output of the circuit
...
The originally circuit used 3 different types of logic
...
The final circuit has five Boolean operators, the same as the original circuit, but now they are all the same
type: NAND
...
The cost of a logic chip is fairly standard, regardless of the type of gates contained
...
(More if the additional wiring is taken into account
...
Placing three chips on a board takes three times as long as placing one chip (even if a robot is doing it)
...
NOR only circuits can also be used with similar results
...
Hudson
35
4 Sequential Logic
Digital & Analogue Devices
13 April, 2014
(Task 3)
Figure 56: 74LS73- Dual JK Flip-flop
A four stage ripple through counter can be constructed using four J-K flip-flops
...
In general, the number of discrete values that a multi-stage ripple through counter produces is given by the
equation:
[0
...
So a four stage counter will have values:
[0
...
(16 β 1)] = [0
...
e
...
This counter can count up to 15, but we wish to count from 0 to 9
...
e
...
This can be achieved
by connecting bits four (MSB) and two to a NAND gate
...
The counter will reach 1010 for a split-second before the output from all four flip-flops is reset to low
(0)
...
(Note: We are not interested in Μ so it is not connected to anything
...
Together they form a binary-code decimal
counter
...
The J and K inputs of each flip-flop are joined together and connected to a high (1) signal
...
A signal generator is connected to the clock (CLK) input of U1:A
...
Hudson
36
Digital & Analogue Devices
13 April, 2014
The output Q from U1:A is connected to the clock (CLK) input of U1:B
...
The output Q from U2:A is connected to the clock (CLK) input of U2:B
...
This toggles the
state of the next stage
...
Figure 57 to Figure 73 shows one complete cycle of the counter
...
MSB '0000' ==> '0'
Figure 58: LSB
...
MSB '0100' ==> '2'
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
MSB '1100' ==> '3'
Figure 61: LSB
...
MSB '1010' ==> '5'
Figure 63: LSB
...
Hudson
38
Digital & Analogue Devices
13 April, 2014
Figure 64: LSB
...
MSB '0001' ==> '8'
Figure 66: LSB
...
MSB '0101' ==> 'A' (10)
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
MSB '1101' ==> 'b' (11)
Figure 69: LSB
...
MSB '1011' ==> '0' (13)
Figure 71: LSB
...
Hudson
40
Digital & Analogue Devices
13 April, 2014
Figure 72: LSB
...
MSB '0000' ==> '0' back to the start
...
Hudson
41
Digital & Analogue Devices
13 April, 2014
Figure 74 shows the timing of the circuit
...
Notice U1A goes high as clock pulse 1 goes from high to low
...
When U1:B goes from high to low (at the end of clock pulse 4), U2:A goes high
...
At the end of clock pulse 16 the count starts over
...
Adapted from (Tangient LLC, 2014)
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
When the counter reaches 1010 (10102 )
it is reset back to zero
...
Those circled in red are all βdonβt careβ states
so we can ignore that group
...
For all four terms βAβ and βCβ are constant
...
π·
The counter (in the previous circuit) can count up to 15, but we wish to count from 0 to 9
...
The counter will reach 1010
for a split-second before the output from all four flip-flops is reset to low (0)
...
Figure 75 to Figure 85 show the counter increment until 1010 is reached, at which point the reset occurs
and the counter starts again at zero
...
Hudson
43
Digital & Analogue Devices
13 April, 2014
Figure 75: LSB
...
MSB '1000' ==> '1'
Figure 77: LSB
...
Hudson
44
Digital & Analogue Devices
13 April, 2014
Figure 78: LSB
...
MSB '0010' ==> '4'
Figure 80: LSB
...
Hudson
45
Digital & Analogue Devices
13 April, 2014
Figure 81: LSB
...
MSB '1110' ==> '7'
Figure 83: LSB
...
Hudson
46
Digital & Analogue Devices
13 April, 2014
Figure 84: LSB
...
MSB '0000' ==> '0' Back to the start
HNC Electrical and Electronic Engineering
Year One: 2013/14
Keith A
...
Starting from the top:
ο·
ο·
ο·
ο·
ο·
A signal generator produces pulses that are connected to the clock (CLK) input of U1:A
...
When U1:A goes from high to low (at the end of clock pulse 2), U1:B goes high
...
When U2:A goes from high to low (at the end of clock pulse 8), U2:B goes high
...
Figure 86: Timing diagram for 0-9 Ripple Counter
...
Hudson
48
Digital & Analogue Devices
13 April, 2014
Figure 87 shows the above circuit wired up using a Digiac 3000-4
...
Figure 87: DIGIAC 3000-4
...
Hudson
49
Digital & Analogue Devices
13 April, 2014
6 Bibliography
Anon
...
d
...
[Online]
Available at: http://www
...
dk/electronics/toolbox/lookuptables/logic
...
Crompton, M
...
Mike C's Homepage
...
humber
...
Crompton/
[Accessed 17 05 2014]
...
EE201: Digital Circuits and Systems
...
eeng
...
ie/~ee201/indexold
...
Jain, R
...
, 2010
...
4th ed
...
Nailis, M
...
L4-HNC-CombinationalLogic-01, Middlesbrough: Middlesbrough College
...
ceng - Flip-Flops
...
wikispaces
...
HNC Electrical and Electronic Engineering
Year One: 2013/14
Title: Circuit Protection and Tariffs
Description: Utilisation of Electrical Energy (UofEE) - Assignment 3. Construction and operation of circuit over-current protection devices and high power circuit breakers. Construction and operation. of ELCB and RCD devices. Definition of energy tariffs - two part structure. Effect of Power Factor on tariff Grade received: DISTINCTION Tutor: Mark Nailis Institute: Middlesbrough College Programme: Higher National Certificate (HNC) in Electrical and Electronic Engineering
Description: Utilisation of Electrical Energy (UofEE) - Assignment 3. Construction and operation of circuit over-current protection devices and high power circuit breakers. Construction and operation. of ELCB and RCD devices. Definition of energy tariffs - two part structure. Effect of Power Factor on tariff Grade received: DISTINCTION Tutor: Mark Nailis Institute: Middlesbrough College Programme: Higher National Certificate (HNC) in Electrical and Electronic Engineering