Features
■Typical propagation delay: 8ns
■Wide power supply range: 2V–6V
■Low quiescent current: 20μA maximum (74HC Series)
■Low input current: 1μA maximum
■Fanout of 10 LS-TTL loads
General Description
The MM74HC00N NAND gates utilize advanced silicongate
CMOS technology to achieve operating speeds
similar to LS-TTL gates with the low power consumption
of standard CMOS integrated circuits. All gates have
buffered outputs. All devices have high noise immunity
and the ability to drive 10 LS-TTL loads. The 74HC logic
family is functionally as well as pin-out compatible with
the standard 74LS logic family. All inputs are protected
from damage due to static discharge by internal diode
clamps to V
CC
and ground.
General Description
The MM74HC00N NAND gates utilize advanced silicongate
CMOS technology to achieve operating speeds
similar to LS-TTL gates with the low power consumption
of standard CMOS integrated circuits. All gates have
buffered outputs. All devices have high noise immunity
and the ability to drive 10 LS-TTL loads. The 74HC logic
family is functionally as well as pin-out compatible with
the standard 74LS logic family. All inputs are protected
from damage due to static discharge by internal diode
clamps to V
CC
and ground.
Feature
General Description
The MM74HC00 NAND gates utilize advanced silicongate CMOS technology to achieve operating speeds similar to LS-TTL gates with the low power consumption of standard CMOS integrated circuits. All gates have buffered outputs. All devices have high noise immunity and the ability to drive 10 LS-TTL loads. The 74HC logic family is functionally as well as pin-out compatible with the standard 74LS logic family. All inputs are protected from damage due to static discharge by internal diode clamps to VCC and ground.
Features
■ Typical propagation delay: 8ns
■ Wide power supply range: 2V–6V
■ Low quiescent current: 20µA maximum (74HC Series)
■ Low input current: 1µA maximum
■ Fanout of 10 LS-TTL loads
Applications
- This product is general usage and suitable for many different applications.
(Picture: Pinout)
