Logic - Signal Switches, Multiplexers, Decoders

Part Number	Description / PDF	Quantity
CBTD3384DB,118 NXP Semiconductors	BUS DRIVER, CBT/FST/QS/5C/B SERI	625
74AUP1G158GM,132 NXP Semiconductors	IC MULTIPLX 1 X 2:1 6XSON/SOT886	4800
74LV251D,118 NXP Semiconductors	IC MULTIPLEXER 1 X 8:1 16SO	0
HEF4066BT-Q100118 NXP Semiconductors	SPST	28810
74AHC257PW112 NXP Semiconductors	74AHC257PW - MULTIPLEXER, AHC/V	2400
74AUP2G157GM,125 NXP Semiconductors	IC MULTIPLEXER 1 X 2:1 8XQFN	167575
74HCT4514PW118 NXP Semiconductors	NOW NEXPERIA 74HCT4514PW - DECOD	4455
74HC153D/S200118 NXP Semiconductors	74HC153 - 4 LINE MUX	27500
CBT3306D,118 NXP Semiconductors	IC BUS SWITCH 1 X 1:1 8SO	14665
74HCT42N,652 NXP Semiconductors	IC DECODER 1 X 4:10 16DIP	3881
74AUP1G18GF/S500132 NXP Semiconductors	IC DEMULTIPLEXER 1 X 1:2 6XSON	96300
74HC157N,652 NXP Semiconductors	IC MULTIPLEXER 4 X 2:1 16DIP	23489
N74F157AD,602 NXP Semiconductors	IC MULTIPLEXER 4 X 2:1 16SO	4358
74AHC1G66GV-Q100125 NXP Semiconductors	SPST	150000
74HCT151N,652 NXP Semiconductors	IC MULTIPLEXER 1 X 8:1 16DIP	0
74HCT138DB,112 NXP Semiconductors	IC DECODER/DEMUX 1X3:8 16SSOP	4368
CBT3245ADS,112 NXP Semiconductors	IC BUS SWITCH 8 X 1:1 20SSOP	13680
NX3L2T66GD NXP Semiconductors	SPST, 2 FUNC, CMOS	0
74LVC1G157GF/S500132 NXP Semiconductors	MUX, 2 LINE INPUT	110000
HEF4051BT/S200118 NXP Semiconductors	SINGLE-ENDED MUX, 8 CHANNEL	10000

Logic - Signal Switches, Multiplexers, Decoders

1. Overview

Signal switches, multiplexers, and decoders are fundamental logic ICs used to manage signal routing and data selection in electronic systems. Signal switches control the flow of electrical signals, multiplexers select between multiple input signals, and decoders convert encoded signals into specific outputs. These components are critical in modern technologies such as telecommunications, computing, and industrial automation, enabling efficient data handling and system design simplification.

2. Main Types and Functional Classification

Type	Functional Features	Application Examples
Signal Switches	Digital/analog switches with on/off control	Audio routing, power management
Multiplexers (MUX)	2:1 to 16:1 channel selection, data bus sharing	Network switches, sensor data aggregation
Decoders	Binary-to-decimal, BCD-to-7-segment conversion	Memory address decoding, display drivers

3. Structure and Composition

These ICs typically use CMOS or TTL technology with standard packages like DIP, SOP, and QFN. Internal components include transistor arrays, logic gates, and channel control circuits. For example, a 4-channel analog switch integrates four independent switching elements in a single package with common control lines.

4. Key Technical Specifications

Parameter	Description	Importance
On-resistance (R_ON)	Resistance in conducting state	Impacts signal integrity
Bandwidth	Maximum signal frequency supported	Determines high-speed capability
Channel count	Number of independent paths	System scalability
Power consumption	Quiescent current and switching loss	Battery life consideration
Propagation delay	Signal transmission time	Critical for timing-sensitive systems

5. Application Areas

Telecommunications: Signal routing in base stations
Automotive: Sensor signal selection in ECUs
Consumer Electronics: HDMI switch boxes
Industrial: PLC signal conditioning
Computing: Memory address decoding in CPUs

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Features
TI	SN74CB3Q3245	10- R_ON, 2.3V-3.6V supply
Analog Devices	ADG1412	4-channel switch, 165MHz bandwidth
NXP	74HC151	8:1 multiplexer, 70MHz operation
STMicroelectronics	CD4028BE	BCD-to-decimal decoder, 18V rating

7. Selection Guidelines

Channel requirements: Match input/output count needs
Signal type: Choose analog/digital switches accordingly
Voltage compatibility: Ensure supply voltage matches system rails
Speed vs. power trade-off: High bandwidth increases consumption
Package constraints: Consider PCB space and thermal requirements

8. Industry Trends

Current developments focus on miniaturization (0.4mm pitch packages), lower on-resistance (<1 ), and integration with level-shifting functions. The rise of IoT and 5G drives demand for high-frequency switches (up to 10GHz) with sub-mW standby power. Advanced CMOS processes enable higher channel density while maintaining signal integrity in automotive-grade temperature ranges.