Card Extenders

Part Number	Description / PDF	Quantity
3690-26 Vector Electronics & Technology, Inc.	CARD EXTND 18/31 ES CT IBM ATISA	0
3690-6 Vector Electronics & Technology, Inc.	CARD EXTENDERS 22 ES CT GEN PURP	3
2000-6U-EXTM-LF Twin Industries	CARD EXTENDERS PCI	7
3690-30 Vector Electronics & Technology, Inc.	CARD EXTENDERS IBM PS/2 66/132	0
3690-17 Vector Electronics & Technology, Inc.	CARD EXTENDERS 28 PER SIDE CT GP	0
3690-26-1 Vector Electronics & Technology, Inc.	CARD EXTENDERS IBM AT-ISA	0
3690-1 Vector Electronics & Technology, Inc.	EXTENDER CARD 3690 W/O CONN AVX	0
VME64J2 Vector Electronics & Technology, Inc.	CARD EXTENDERS 160 PINS CT VME	0
UEC220-6U Vector Electronics & Technology, Inc.	CARD EXTENDER 64 PINS CT GEN PUR	0
EB220-3U Vector Electronics & Technology, Inc.	CARD EXTENDERS BLANK	0
3690-18# Vector Electronics & Technology, Inc.	CARD EXTENDR 30/43 ES CT GEN PUR	0
UEB500-9U Vector Electronics & Technology, Inc.	CARD EXTENDER TEST UNIV 9UX500MM	0
UEB220-9U Vector Electronics & Technology, Inc.	CARD EXTENDERS 96 PINS CONTACTS	0
3690-28 Vector Electronics & Technology, Inc.	CARD EXTENDERS MAC II	0
UEB400-9U Vector Electronics & Technology, Inc.	CARD EXTENDER TEST UNIV 9UX400MM	0
VVL-5080 Vector Electronics & Technology, Inc.	CARD EXTENDERS VME LOAD BRD VXI	0
3690-3 Vector Electronics & Technology, Inc.	CARD EXTENDERS 22 ES CT GEN PURP	0
3690-31 Vector Electronics & Technology, Inc.	CARD EXTENDER BD IBM PS/2 MOD 80	0
VME64J1J2 Vector Electronics & Technology, Inc.	CARD EXTENDERS 160 PINS CT VME	0
7586-MINI Twin Industries	CARD EXTENDERS PCI MINI	0

Card Extenders

Card extenders are modular hardware components designed to expand the functionality of prototyping platforms (e.g., development boards, PCBs) by providing additional interfaces, connectors, or circuitry. They play a critical role in rapid prototyping, enabling engineers to test and integrate peripheral devices without redesigning core systems. Their importance lies in accelerating product development cycles, reducing costs, and supporting flexible design iterations in electronics, IoT, and embedded systems.

Type	Functional Features	Application Examples
Bus Extenders	Expand PCIe/USB/CAN bus interfaces	Industrial automation controllers
Sensor Adapters	Bridge analog/digital sensors to MCUs	Environmental monitoring systems
Communication Modules	Integrate Wi-Fi/BLE/LoRa transceivers	Smart home device prototypes
Power Management Boards	Provide voltage regulation/isolation	Portable medical devices

A typical card extender comprises: - Base PCB: FR4 material with copper traces - Connectors: High-density headers (e.g., 0.1" pitch) or edge fingers - Signal Conditioning Circuits: Level shifters, filters, or amplifiers - Mounting Hardware: Standoffs and screw holes for mechanical stability - Interface Chips: Protocol converters (e.g., USB-to-SPI bridges)

Parameter	Importance
Interface Compatibility	Ensures seamless integration with host platforms
Signal Integrity	Measured via insertion loss (<1dB at 10Gbps)
Operating Temperature	-40 C to +85 C for industrial reliability
EMI Shielding	Reduces interference (30-100MHz attenuation)
Modular Scalability	Supports daisy-chaining up to 5 devices

Primary industries include: - Electronics R&D: FPGA prototyping boards - Industrial Automation: PLC expansion modules - Telecom: 5G base station test equipment - Education: STEM learning kits for robotics - Medical Devices: Diagnostic equipment prototypes

Manufacturer	Representative Product
Adafruit Industries	FeatherWing CAN Bus Module
SparkFun Electronics	Qwiic Mux Breakout
STMicroelectronics	X-NUCLEO Expansion Boards
TE Connectivity	MicroTCA Carrier Hubs

Key considerations: - Match host interface (e.g., Arduino Shield vs. Raspberry Pi HAT) - Verify voltage level compatibility (3.3V vs. 5V) - Assess required bandwidth (e.g., SPI vs. Gigabit Ethernet) - Environmental requirements (IP rating for outdoor use) - Cost vs. performance trade-offs (e.g., basic vs. EMI-shielded models)

Emerging trends include: - Integration of AI accelerators in extender modules - Development of ultra-compact (sub-10mm) form factors - Adoption of open-source hardware standards (e.g., RISC-V compatibility) - Increased focus on energy-efficient designs for IoT edge devices - Growth in reconfigurable FPGA-based extenders for adaptive computing