Clock/Timing - Clock Buffers, Drivers

Part Number	Description / PDF	Quantity
CY23FP12OC Rochester Electronics	PLL BASED CLOCK DRIVER	1345
W152-12GT Rochester Electronics	PLL BASED CLOCK DRIVER	10000
CY2PD817ZC Rochester Electronics	LOW SKEW CLOCK DRIVER	3803
CY2CC1810OI Rochester Electronics	LOW SKEW CLOCK DRIVER	29811
CGS74C2525M Rochester Electronics	1 TO 8 MINIMUM SKEW CLOCK DRIVE	0
CY2PP3210AI Rochester Electronics	LOW SKEW CLOCK DRIVER	329
CY7B9911V-5JCT Rochester Electronics	LOW SKEW CLOCK DRIVER	18
CY23S05SC-1H Rochester Electronics	PLL BASED CLOCK DRIVER	291
CY2544C011 Rochester Electronics	PROGRAMMABLE CLOCK GENERATOR	4513
CY2CC810OI Rochester Electronics	LOW SKEW CLOCK DRIVER	12313
CY23020LFI-3 Rochester Electronics	PLL BASED CLOCK DRIVER	4930
CY7B9911V-7JXCT Rochester Electronics	LOW SKEW CLOCK DRIVER	18000
CY2308SI-1HT Rochester Electronics	PLL BASED CLOCK DRIVER	2435
CY2305ESXC-1HT Rochester Electronics	CLOCK DRIVER, 2305 SERIES	2500
PY26210SC Rochester Electronics	PACKETCLOCK CLOCK TRANSLATOR	11564
CY7B992-2JCT Rochester Electronics	PLL BASED CLOCK DRIVER	3026
CY2310ANZPVC-1 Rochester Electronics	LOW SKEW CLOCK DRIVER	1515
CY7B992-5JC Rochester Electronics	PLL CLOCK DRIVER	338
W194-70G Rochester Electronics	PLL BASED CLOCK DRIVER	782
IMIZ9973BA Rochester Electronics	PLL BASED CLOCK DRIVER	18116

Clock/Timing - Clock Buffers, Drivers

1. Overview

Clock buffers and drivers are integrated circuits (ICs) designed to distribute clock signals in electronic systems. They amplify, condition, and route timing signals to multiple destinations while minimizing skew, jitter, and signal degradation. These components are critical in synchronizing operations across processors, memory modules, communication interfaces, and other timing-sensitive circuits. Their importance spans industries such as telecommunications, automotive, and high-performance computing.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Clock Buffers	Single-input, multiple-output devices with low phase noise and skew	CPU clock distribution, FPGA systems
Clock Drivers	High-drive capability for fan-out applications	Networking switches, server motherboards
Differential Clock Buffers	Supports LVDS, HCSL, and CML signal types	High-speed ADC/DAC systems, RF transceivers
Programmable Clock Buffers	Configurable output frequency/division ratios	Industrial automation, test equipment

3. Structure and Composition

Clock buffers/drivers typically consist of:

Input receivers (single-ended or differential)
Internal amplification stages
Output drivers with controlled impedance
Power supply decoupling structures
Thermal management pads (in QFN/SSOP packages)

They are fabricated using CMOS, Bipolar, or SiGe processes to optimize speed and noise performance.

4. Key Technical Specifications

Parameter	Description	Importance
Max Operating Frequency	Up to 1.2 GHz (CMOS), 3.2 GHz (SiGe)	Determines application suitability for high-speed systems
Additive Phase Jitter	0.05 ps RMS to 1 ps RMS	Impacts timing precision in data converters
Propagation Delay	50 ps to 5 ns	Critical in synchronized multi-channel systems
Output Voltage Levels	LVCMOS, LVDS, HSTL, etc.	Ensures compatibility with downstream circuits
Supply Voltage	1.8V to 5V	Affects power consumption and integration

5. Application Areas

Telecommunications: 5G base stations, optical transceivers
Computing: Servers, workstations, high-end PCs
Industrial: PLCs, motor controllers, test instruments
Automotive: ADAS clock synchronization, infotainment systems

Case Study: In 5G massive MIMO systems, low-jitter clock drivers ensure phase coherence across 64+ antenna elements.

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Specifications
TI (Texas Instruments)	CDCE62005	3.2 GHz LVDS driver, 0.1 ps RMS jitter
Analog Devices	ADCLK846	16-output clock buffer, 1.6 GHz bandwidth
STMicroelectronics	DF1610S	1.8V/3.3V dual supply buffer, 8 outputs
ON Semiconductor	MC100EP195	Differential ECL buffer, 2.5 GHz operation

7. Selection Recommendations

Key considerations:

Match output type to receiver requirements (LVDS/CML/LVCMOS)
Calculate required fan-out capacity with voltage margin
Specify jitter budget (e.g., <0.3 ps RMS for 10 Gbps SerDes)
Consider temperature stability (-40 C to +125 C automotive grade)
Optimize package size vs. thermal dissipation needs

8. Industry Trends

Future developments include:

Sub-100 fs jitter performance using advanced CMOS processes
Integration with PLL/VCO for clock generation
Multi-die packaging for hybrid signal conditioning
Energy-efficient designs for battery-powered IoT devices
Automotive-grade ICs with AEC-Q100 qualification