74HC190 Datasheet, PDF(2/13 Page) NXP Semiconductors – Presettable synchronous BCD decade up/down counter

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74HC190 Datasheet, PDF (2/13 Pages) NXP Semiconductors – Presettable synchronous BCD decade up/down counter

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Philips Semiconductors

Presettable synchronous BCD decade

up/down counter

Product speciï¬cation

74HC/HCT190

FEATURES

â¢ Synchronous reversible counting

â¢ Asynchronous parallel load

â¢ Count enable control for synchronous expansion

â¢ Single up/down control input

â¢ Output capability: standard

â¢ ICC category: MSI

GENERAL DESCRIPTION

The 74HC/HCT190 are high-speed Si-gate CMOS devices

and are pin compatible with low power Schottky TTL

(LSTTL). They are specified in compliance with JEDEC

standard no. 7A.

The 74HC/HCT190 are asynchronously presettable

up/down BCD decade counters. They contain four

master/slave flip-flops with internal gating and steering

logic to provide asynchronous preset and synchronous

count-up and count-down operation.

Asynchronous parallel load capability permits the counter

to be preset to any desired number. Information present on

the parallel data inputs (D0 to D3) is loaded into the counter

and appears on the outputs when the parallel load (PL)

input is LOW. As indicated in the function table, this

operation overrides the counting function.

Counting is inhibited by a HIGH level on the count enable

(CE) input. When CE is LOW internal state changes are

initiated synchronously by the LOW-to-HIGH transition of

the clock input. The up/down (U/D) input signal determines

the direction of counting as indicated in the function table.

The CE input may go LOW when the clock is in either

state, however, the LOW-to-HIGH CE transition must

occur only when the clock is HIGH. Also, the U/D input

should be changed only when either CE or CP is HIGH.

Overflow/underflow indications are provided by two types

of outputs, the terminal count (TC) and ripple clock (RC).

The TC output is normally LOW and goes HIGH when a

circuit reaches zero in the count-down mode or reaches â9â

in the count-up-mode. The TC output will remain HIGH

until a state change occurs, either by counting or

presetting, or until U/D is changed. Do not use the TC

output as a clock signal because it is subject to decoding

spikes. The TC signal is used internally to enable the RC

output. When TC is HIGH and CE is LOW, the RC output

follows the clock pulse (CP). This feature simplifies the

design of multistage counters as shown in Figs 5 and 6.

In Fig.5, each RC output is used as the clock input to the

next higher stage. It is only necessary to inhibit the first

stage to prevent counting in all stages, since a HIGH on

CE inhibits the RC output pulse as indicated in the function

table. The timing skew between state changes in the first

and last stages is represented by the cumulative delay of

the clock as it ripples through the preceding stages. This

can be a disadvantage of this configuration in some

applications.

Fig.6 shows a method of causing state changes to occur

simultaneously in all stages. The RC outputs propagate

the carry/borrow signals in ripple fashion and all clock

inputs are driven in parallel. In this configuration the

duration of the clock LOW state must be long enough to

allow the negative-going edge of the carry/borrow signal to

ripple through to the last stage before the clock goes

HIGH. Since the RC output of any package goes HIGH

shortly after its CP input goes HIGH there is no such

restriction on the HIGH-state duration of the clock.

In Fig.7, the configuration shown avoids ripple delays and

their associated restrictions. Combining the TC signals

from all the preceding stages forms the CE input for a

given stage. An enable must be included in each carry

gate in order to inhibit counting. The TC output of a given

stage it not affected by its own CE signal therefore the

simple inhibit scheme of Figs 5 and 6 does not apply.

December 1990

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