Philips 74HCT9323D, 74HC9323D Datasheet




74HC/HCT9323A

Programmable ripple counter with
oscillator (3-State)

Objective specification 1995 Oct 27

INTEGRATED CIRCUITS

IC06 Data Handbook

Philips Semiconductors Objective specification

74HC/HCT9323A

Programmable ripple counter with oscillator
(3-State)

2

1995 Oct 27

FEATURES

•8-pin space saving package

•Programmable 3-stage ripple counter

•Suitable for over-tone crystal application up to 85MHz

(V

CC

= 5V10%)

•3-State output buffer

•Two internal capacitors

•Recommended operating range for use with third overtone

crystals 3V to 6V

•Oscillator stop function (MR)

•Output capability:

bus driver  (15 LSTTL)

•I

CC

category: MSI

APPLICATIONS

•Control counters

•Timers

•Frequency dividers

•Time-delay circuits

•CIO (Compact Integrated Oscillator)

•Third-overtone crystal operation

DESCRIPTION

The 74HC/HCT9323A are high-speed Si-gate CMOS devices. They
are specified in compliance with JEDEC standard no. 7A.

The HC/HCT 9323A are oscillators designed for quartz crystal
combined with a programmable 3-State counter, a 3-State output
buffer and an overriding asynchronous master reset (MR

). With the
two select inputs S1 and S2 the counter can be switched in the
divide-1, 2, 4 or 8 mode. If left floating the clock is divided by 8. The
oscillator is designed to operate either in the fundamental or third
overtone mode depending on the crystal and external components
applied. On-chip capacitors minimize external component count for
third overtone crystal applications.

The oscillator may be replaced by an external clock signal at input
X1. In this event the other oscillator pin (X2) must be floating. The
counter advances on the negative-going transition of X1. A LOW
level on MR

resets the counter, stops the oscillator and sets the

output buffer in the 3-State condition. MR

can be left floating since

an internal pull-up resistor will make the MR

inactive. In the HCT

version, the MR

input and the two mode select pins S1 and S2 are
TTL compatible, but the X1 input has CMOS input switching levels
and may be driven by a TTL output using a pull-up resistor
connected to V

CC

.

QUICK REFERENCE DA TA

GND = 0V; T

amb

= 25°C, tr = tf = 6ns

SYMBOL

PARAMETER

CONDITIONS

T

amb

= 25°C; GND = 0V

TYPICAL UNIT

HC HCT

t

PLH

t

PHL

Propagation delay
X1 to OUT (S1 = S2 = LOW)

CL = 50pF; VCC = 5V 8 8 ns

f

max

Maximum clock frequency 150 150 MHz

C

I

Input capacitance except X1 and X2 3.5 3.5 pF

C

PD

Power dissipation
capacitance per package

pF

NOTES:

C

PD

is used to determine the dynamic power dissipation (PD in µW):

P

D

=(CPD  V

CC

2

 fI) + (CL + V

CC

2

 fO) + (I

pull-up

 VCC)
where:
f

I

= inputfrequency in MHz..

f

O

= output frequency in MHz.

V

CC

= Supply voltage in V.

C

L

= Output load capacitance in pF.

I

pull-up

= Pull-up currents in µA.

For HC and HCT an external clock is applied to X1 with:

t

r

= tf  6ns, VI is GND to VCC, MR = HIGH.

I

pull-up

is the summation of –II (µA) of S1 and S2 inputs at the LOW state.

ORDERING INFORMATION

PACKAGES TEMPERATURE RANGE ORDER NUMBER DWG NUMBER

8-Pin Plastic SO 0°C to +70°C 74HC/HCT9323A D SOT96-1