18-Bit Registered Transceiver
CY74FCT163500
SCCS066 - June 1997 - Revised March 2000
Data sheet acquired from Cypress Semiconductor Corporation.
Data sheet modified to remove devices not offered.
Copyright
©
2000, Texas Instruments Incorporated
Features
• Low power, pin-compatible replacement for LCX and
LPT families
• 5V tolerant inputs and outputs
• 24 mA balanced drive outputs
• Power-off disable outputs permits live insertion
• Edge-rate control circuitry for reduced noise
• FCT-C speed at 4.6 ns
• Latch-up performance exceeds JEDEC standard no. 17
• ESD > 2000V per MIL-STD-883D, Method 3015
• Typical output skew < 250ps
• Industrial temperature range of –40˚C to +85˚C
• TSSOP (19.6-mil pitch) or SSOP (25-mil pitch)
• Typical V
olp
(ground bounce) performance exceeds Mil
Std 883D
• V
CC
= 2.7V to 3.6V
Functional Description
The CY74FCT163500 is an 18-bit universal bus transceiver
that can be operated in transparent, latched, or clock modes
by combining D-type latches and D-type flip-flops. Data flow in
each direction is controlled by output-enable (OEAB and
OEBA), latch enable (LEAB and LEBA), and clock inputs
(CLKAB and CLKBA) inputs. For A-to-B data flow, the device
operates in transparent mode when LEAB is HIGH. When
LEAB is LOW, the A data is latched if CLKAB is held at a HIGH
or LOW logic level. If LEAB is LOW, the A bus data is stored in
the latch/flip-flop on the HIGH-to-LOW transition of CLKAB.
OEAB performs the output enable function on the B port. Data
flow from B-to-A is similar to that of A-to-B and is controlled by
OEBA, LEBA, and CLKBA.
The CY74FCT163500 has 24-mA balanced output drivers
with current limiting resistors in the outputs. This reduces the
need for external terminating resistors and provides for
minimal undershoot and reduced ground bounce.The inputs
and outputs are capable of being driven by 5.0V busses,
allowing them to be used in mixed voltage systems as
translators. The outputs are also designed with a power off
disable feature enabling them to be used in applications
requiring live insertion.
GND
Logic Block Diagram
Pin Configuration
1
2
3
4
5
6
7
8
9
10
11
12
33
32
31
30
29
36
35
OEAB
34
SSOP/TSSOP
Top View
13
14
15
16
17
18
19
20
21
22
23
24
45
44
43
42
41
37
38
39
40
48
47
46
LEAB
A
1
A
2
A
3
B
1
B
2
B
3
GND
GND
GND
V
CC
A
6
A
7
A
4
A
5
B
4
B
5
B
6
B
7
V
CC
GND
A
10
A
11
A
8
A
9
B
8
B
9
B
11
B
12
GND
A
12
V
CC
A
16
GND
A
14
V
CC
A
15
A
17
TO 17 OTHER CHANNELS
LEAB
OEBA
LEBA
CLKAB
CLKBA
OEAB
C
D
C
D
C
D
C
D
A
1
B
1
25
26
27
28
49
52
51
50
A
13
OEBA
LEBA
GND
A
18
CLKAB
53
56
55
54
B
10
GND
B
14
B
15
B
13
B
16
B
17
GND
B
18
CLKBA
CY74FCT163500
2
Maximum Ratings
[5, 6]
(Above which the useful life may be impaired. For user
guidelines, not tested.)
Storage Temperature ................................
−
55
°
C to +125
°
C
Ambient Temperature with
Power Applied
................................................. −
55
°
C to +125
°
C
Supply Voltage Range ..................................... 0.5V to +4.6V
DC Input Voltage
.................................................−
0.5V to +7.0V
DC Output Voltage
..............................................−
0.5V to +7.0V
DC Output Current
(Maximum Sink Current/Pin)
...........................−
60 to +120 mA
Power Dissipation .......................................................... 1.0W
Static Discharge Voltage............................................>2001V
(per MIL-STD-883, Method 3015)
Notes:
1.
H = HIGH Voltage Level. L = LOW Voltage Level. X = Don’t Care. Z = HIGH Impedance.
= HIGH-to-LOW Transition.
2.
A-to-B data flow is shown, B-to-A data flow is similar but uses OEBA, LEBA, and CLKBA.
3.
Output level before the indicated steady-state input conditions were established.
4.
Output level before the indicated steady-state input conditions were established, provided that CLKAB was LOW before LEAB went LOW.
5.
Operation beyond the limits set forth may impair the useful life of the device. Unless noted, these limits are over the operating free-air temperature range.
6.
Unused inputs must always be connected to an appropriate logic voltage level, preferably either V
CC
or ground.
Pin Summary
Name
Description
OEAB
A-to-B Output Enable Input
OEBA
B-to-A Output Enable Input (Active LOW)
LEAB
A-to-B Latch Enable Input
LEBA
B-to-A Latch Enable Input
CLKAB
A-to-B Clock Input (Active LOW)
CLKBA
B-to-A Clock Input (Active LOW)
A
A-to-B Data Inputs or B-to-A Three-State Outputs
B
B-to-A Data Inputs or A-to-B Three-State Outputs
Function Table
[1, 2]
Inputs
Outputs
OEAB
LEAB
CLKAB
A
B
L
X
X
X
Z
H
H
X
L
L
H
H
X
H
H
H
L
L
L
H
L
H
H
H
L
H
X
B
[3]
H
L
L
X
B
[4]
Operating Range
Range
Ambient
Temperature
V
CC
Industrial
−
40
°
C to +85
°
C
2.7V to 3.6V
CY74FCT163500
3
Electrical Characteristics
Over the Operating Range V
CC
=2.7V to 3.6V
Parameter
Description
Test Conditions
Min.
Typ.
[7]
Max.
Unit
V
IH
Input HIGH Voltage
All Inputs
2.0
5.5
V
V
IL
Input LOW Voltage
0.8
V
V
H
Input Hysteresis
[8]
100
mV
V
IK
Input Clamp Diode Voltage
V
CC
=Min., I
IN
=
−
18 mA
−
0.7
−
1.2
V
I
IH
Input HIGH Current
V
CC
=Max., V
I
=5.5V
±
1
µ
A
I
IL
Input LOW Current
V
CC
=Max., V
I
=GND.
±
1
µ
A
I
OZH
High Impedance Output Current
(Three-State Output pins)
V
CC
=Max., V
OUT
=5.5V
±
1
µ
A
I
OZL
High Impedance Output Current
(Three-State Output pins)
V
CC
=Max., V
OUT
=GND
±
1
µ
A
I
ODL
Output LOW Current
[9]
V
CC
=3.3V, V
IN
=V
IH
or V
IL
, V
OUT
=1.5V
45
180
mA
I
ODH
Output HIGH Current
[9]
V
CC
=3.3V, V
IN
=V
IH
or V
IL
, V
OUT
=1.5V
–45
–180
mA
V
OH
Output HIGH Voltage
V
CC
=Min., I
OH
= –0.1 mA
V
CC
–0.2
V
V
CC
=3.0V, I
OH
= –8 mA
2.4
3.0
V
V
CC
=3.0V, I
OH
= –24 mA
2.0
3.0
V
V
OL
Output LOW Voltage
V
CC
=Min., I
OL
= 0.1mA
0.2
V
V
CC
=Min., I
OL
= 24 mA
0.3
0.5
I
OS
Short Circuit Current
[9]
V
CC
=Max., V
OUT
=GND
–60
–135
–240
mA
I
OFF
Power-Off Disable
V
CC
=0V, V
OUT
≤
4.5V
±
100
µ
A
Capacitance
[8]
(T
A
= +25˚C, f = 1.0 MHz)
Parameter
Description
Test Conditions
Typ.
[7]
Max.
Unit
C
IN
Input Capacitance
V
IN
= 0V
4.5
6.0
pF
C
OUT
Output Capacitance
V
OUT
= 0V
5.5
8.0
pF
Notes:
7.
Typical values are at V
CC
=3.3V, T
A
= +25˚C ambient.
8.
This parameter is specified but not tested.
9.
Not more than one output should be shorted at a time. Duration of short should not exceed one second. The use of high-speed test apparatus and/or sample
and hold techniques are preferable in order to minimize internal chip heating and more accurately reflect operational values. Otherwise prolonged shorting of
a high output may raise the chip temperature well above normal and thereby cause invalid readings in other parametric tests. In any sequence of parameter
tests, I
OS
tests should be performed last.
CY74FCT163500
4
Power Supply Characteristics
Parameter
Description
Test Conditions
Typ.
[7]
Max.
Unit
I
CC
Quiescent Power Supply Cur-
rent
V
CC
=Max.
V
IN
≤
0.2V,
V
IN
≥
V
CC
−
0.2V
0.1
10
µ
A
∆
I
CC
Quiescent Power Supply Cur-
rent (TTL inputs HIGH)
V
CC
=Max.
V
IN
=V
CC
–0.6V
[10]
2.0
30
µ
A
I
CCD
Dynamic Power Supply
Current
[11]
V
CC
=Max., One Input Toggling,
50%DutyCycle,OutputsOpen,
OEAB=OEBA=V
CC
or GND
V
IN
=V
CC
or
V
IN
=GND
50
75
µ
A/MHz
I
C
Total Power Supply Current
[12]
V
CC
=Max., f
0
=10 MHz
(CLKAB), f
1
=5 MHz, 50% Duty
Cycle, Outputs Open,
One Bit Toggling,
OEAB=OEBA=V
CC
LEAB=GND
V
IN
=V
CC
or
V
IN
=GND
0.5
0.8
mA
V
IN
=V
CC
–0.6V or
V
IN
=GND
0.5
0.8
mA
V
CC
=Max., f
0
=10 MHz,
f
1
=2.5 MHz, 50% Duty
Cycle, Outputs Open,
Eighteen Bits Toggling,
OEAB=OEBA=V
CC
LEAB=GND
V
IN
=V
CC
or
V
IN
=GND
2.5
3.8
[13]
mA
V
IN
=V
CC
–0.6V or
V
IN
=GND
2.6
4.1
[13]
mA
Notes:
10. Per TTL driven input; all other inputs at V
CC
or GND.
11. This parameter is not directly testable, but is derived for use in Total Power Supply calculations.
12. I
C
=
I
QUIESCENT
+ I
INPUTS
+ I
DYNAMIC
I
C
=
I
CC
+
∆
I
CC
D
H
N
T
+I
CCD
(f
0
N
C
/2 + f
1
N
1
)
I
CC
=
Quiescent Current with CMOS input levels
∆
I
CC
=
Power Supply Current for a TTL HIGH input (V
IN
=3.4V)
D
H
=
Duty Cycle for TTL inputs HIGH
N
T
=
Number of TTL inputs at D
H
I
CCD
=
Dynamic Current caused by an input transition pair (HLH or LHL)
f
0
=
Clock frequency for registered devices, otherwise zero
N
C
=
Number of clock inputs changing at f
1
f
1
=
Input signal frequency
N
1
=
Number of inputs changing at f
1
All currents are in milliamps and all frequencies are in megahertz.
13. Values for these conditions are examples of the I
CC
formula. These limits are specified but not tested.
CY74FCT163500
5
Switching Characteristics
Over the Operating Range V
CC
= 3.0V to 3.6V
[,14, 15]
CY74FCT163500A
CY74FCT163500C
Fig. No.
[16]
Parameter
Description
Min.
Max.
Min.
Max.
Unit
f
MAX
CLKAB or CLKBA frequency
150
150
MHz
t
PLH
t
PHL
Propagation Delay
A to B or B to A
1.5
5.1
1.5
4.6
ns
1, 3
t
PLH
t
PHL
Propagation Delay
LEBA to A, LEAB to B
1.5
5.6
1.5
5.3
ns
1, 5
t
PLH
t
PHL
Propagation Delay
CLKBA to A, CLKAB to B
1.5
5.6
1.5
5.3
ns
1, 5
t
PZH
t
PZL
Output Enable Time
OEBA to A, OEAB to B
1.5
6.0
1.5
5.4
ns
1, 7, 8
t
PHZ
t
PLZ
Output Disable Time
OEBA to A, OEAB to B
1.5
5.6
1.5
5.2
ns
1, 7, 8
t
SU
Set-Up Time, HIGH or LOW
A to CLKAB, B to CLKBA
3.0
3.0
ns
9
t
H
Hold Time, HIGH or LOW
A to CLKAB, B to CLKBA
0
0
ns
9
t
SU
Set-Up Time, HIGH or LOW
A to LEAB, B to LEBA
Clock HIGH
3.0
3.0
ns
4
Clock LOW
1.5
1.5
ns
4
t
H
Hold Time, HIGH or LOW
A to LEAB, B to LEBA
1.5
1.5
ns
4
t
W
LEAB or LEBA Pulse Width HIGH
3.0
2.5
ns
5
t
W
CLKAB or CLKBA Pulse Width HIGH or LOW
3.0
3.0
ns
5
t
SK(O)
Output Skew
[17]
0.5
0.5
ns
Ordering Information CY74FCT163500
Speed
(ns)
Ordering Code
Package
Name
Package Type
Operating
Range
4.6
CY74FCT163500CPACT
Z56
56-Lead (240-Mil) TSSOP
Industrial
CY74FCT163500CPVC/PVCT
O56
56-Lead (300-Mil) SSOP
5.1
CY74FCT163500APVC/PVCT
O56
56-Lead (300-Mil) SSOP
Industrial
Notes:
14. Minimum limits are specified but not tested on Propagation Delays.
15. For V
CC
=2.7, propagation delay, output enable and output disable times should be degraded by 20%.
16. See “Parameter Measurement Information” in the General Information section.
17. Skew between any two outputs of the same package switching in the same direction. This parameter is ensured by design.
CY74FCT163500
6
Package Diagrams
56-Lead Shrunk Small Outline Package O56
56-Lead Thin Shrunk Small Outline Package Z56
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Copyright
©
2000, Texas Instruments Incorporated