NSC 54F163ALMQB, 54F163ADMQB, 54F163ADM, 54F163ADC Datasheet

TL/F/9486

54F/74F161A

#

54F/74F163A Synchronous Presettable Binary Counter

November 1994

54F/74F161A#54F/74F163A
Synchronous Presettable Binary Counter

General Description

The ’F161A and ’F163A are high-speed synchronous modu­lo-16 binary counters. They are synchronously presettable
for application in programmable dividers and have two types
of Count Enable inputs plus a Terminal Count output for
versatility in forming synchronous multi-stage counters. The
’F161A has an asynchronous Master-Reset input that over­rides all other inputs and forces the outputs LOW. The
’F163A has a Synchronous Reset input that overrides
counting and parallel loading and allows the outputs to be
simultaneously reset on the rising edge of the clock. The
’F161A and ’F163A are high-speed versions of the ’F161
and ’F163.

Features

Y

Synchronous counting and loading

Y

High-speed synchronous expansion

Y

Typical count frequency of 120 MHz

Y

Guaranteed 4000V minimum ESD protection

Commercial Military

Package

Package Description

Number

74F161APC N16E 16-Lead (0.300×Wide) Molded Dual-In-Line

54F161ADM (Note 2) J16A 16-Lead Ceramic Dual-In-Line

74F161ASC (Note 1) M16A 16-Lead (0.150×Wide) Molded Small Outline, JEDEC

74F161ASJ (Note 1) M16D 16-Lead (0.300×Wide) Molded Small Outline, EIAJ

54F161AFM (Note 2) W16A 16-Lead Cerpack

54F161ALM (Note 2) E20A 20-Lead Ceramic Leadless Chip Carrier, Type C

74F163APC N16E 16-Lead (0.300×Wide) Molded Dual-In-Line

54F163ADM (Note 2) J16A 16-Lead Ceramic Dual-In-Line

74F163ASC (Note 1) M16A 16-Lead (0.150×Wide) Molded Small Outline, JEDEC

74F163ASJ (Note 1) M16D 16-Lead (0.300×Wide) Molded Small Outline, EIAJ

54F163AFM (Note 2) W16A 16-Lead Cerpack

54F163ALM (Note 2) E20A 20-Lead Ceramic Leadless Chip Carrier, Type C

Note 1: Devices also available in 13×reel. Use suffixeSCX and SJX.
Note 2: Military grade device with environmental and burn-in processing. Use suffix

e

DMQB, FMQB and LMQB.

Connection Diagrams

Pin Assignment

for DIP, SOIC and Flatpak

’F161A

TL/F/9486– 1

Pin Assignment

for LCC

’F161A

TL/F/9486– 2

Pin Assignment

for DIP, SOIC and Flatpak

’F163A

TL/F/9486– 7

Pin Assignment

for LCC

’F163A

TL/F/9486– 8

TRI-STATEÉis a registered trademark of National Semiconductor Corporation.

C

1995 National Semiconductor Corporation RRD-B30M75/Printed in U. S. A.

Logic Symbols

’F161A

TL/F/9486– 3

IEEE/IEC

’F161A

TL/F/9486– 6

’F163A

TL/F/9486– 9

IEEE/IEC

’F163A

TL/F/9486– 10

Unit Loading/Fan Out

54F/74F

Pin Names Description

U.L. Input I

IH/IIL

HIGH/LOW Output IOH/I

OL

CEP Count Enable Parallel Input 1.0/1.0 20 mA/b0.6 mA
CET Count Enable Trickle Input 1.0/2.0 20 mA/

b

1.2 mA

CP Clock Pulse Input (Active Rising Edge) 1.0/1.0 20 mA/

b

0.6 mA
MR (’F161A) Asynchronous Master Reset Input (Active LOW) 1.0/1.0 20 mA/b0.6 mA
SR

(’F163A) Synchronous Reset Input (Active LOW) 1.0/2.0 20 mA/b1.2 mA

P0–P

3

Parallel Data Inputs 1.0/1.0 20 mA/b0.6 mA

PE

Parallel Enable Input (Active LOW) 1.0/2.0 20 mA/b1.2 mA

Q

0–Q3

Flip-Flop Outputs 50/33.3

b

1 mA/20 mA

TC Terminal Count Output 50/33.3

b

1 mA/20 mA

2

Functional Description

The ’F161A and ’F163A count in modulo-16 binary se­quence. From state 15 (HHHH) they increment to state 0
(LLLL). The clock inputs of all flip-flops are driven in parallel
through a clock buffer. Thus all changes of the Q outputs
(except due to Master Reset of the ’F161A) occur as a re­sult of, and synchronous with, the LOW-to-HIGH transition
of the CP input signal. The circuits have four fundamental
modes of operation, in order of precedence: asynchronous
reset (’F161A), synchronous reset (’F163A), parallel load,
count-up and hold. Five control inputsÐMaster Reset (MR

,

’F161A), Synchronous Reset (SR

, ’F163A), Parallel Enable

(PE

), Count Enable Parallel (CEP) and Count Enable Trickle
(CET)Ðdetermine the mode of operation, as shown in the
Mode Select Table. A LOW signal on MR

overrides all other
inputs and asynchronously forces all outputs LOW. A LOW
signal on SR

overrides counting and parallel loading and
allows all outputs to go LOW on the next rising edge of CP.
A LOW signal on PE

overrides counting and allows informa-

tion on the Parallel Data (P

n

) inputs to be loaded into the

flip-flops on the next rising edge of CP. With PE

and MR
(’F161A) or SR (’F163A) HIGH, CEP and CET permit count­ing when both are HIGH. Conversely, a LOW signal on ei­ther CEP or CET inhibits counting.

The ’F161A and ’F163A use D-type edge triggered flip-flops
and changing the SR

,PE, CEP and CET inputs when the CP
is in either state does not cause errors, provided that the
recommended setup and hold times, with respect to the ris­ing edge of CP, are observed.

The Terminal Count (TC) output is HIGH when CET is HIGH
and the counter is in state 15. To implement synchronous
multi-stage counters, the TC outputs can be used with the
CEP and CET inputs in two different ways. Please refer to
the ’F568 data sheet. The TC output is subject to decoding
spikes due to internal race conditions and is therefore not
recommended for use as a clock or asynchronous reset for
flip-flops, counters or registers.

Logic Equations: Count Enable

e

CEP#CET#PE

TCeQ

0

#

Q

1

#

Q

2

#

Q

3

#

CET

Mode Select Table

*SR PE CET CEP

Action on the Rising

Clock Edge (L)

L X X X Reset (Clear)

H L X X Load (P

n

x

Qn)
H H H H Count (Increment)
H H L X No Change (Hold)
H H X L No Change (Hold)

*For ’F163A only

H

e

HIGH Voltage Level

L

e

LOW Voltage Level

X

e

Immaterial

State Diagram

TL/F/9486– 5

3