Send an Inquiry

To receive a quote for your project, please fill in the following information, and we’ll get back to you promptly.

Submit Inventory List

Please fill in the following information, and we’ll get back to you promptly.

Home > Products > Integrated Circuits (ICs) > Embedded > CPLDs (Complex Programmable Logic Devices)

AMD XC95144XL-10TQG144C

Name: XC95144XL-10TQG144C
Brand: AMD
SKU: XC95144XL-10TQG144C
Price: 2.40 USD
Availability: InStock
Rating: 5 (2 reviews)

Compare

Part No.:: XC95144XL-10TQG144C

Manufacturer:: AMD

Category:: CPLDs (Complex Programmable Logic Devices)

Package:: 144-LQFP

Datasheet:: XC95144XL-10TQG144C.pdf

Description:: IC CPLD 144MC 10NS 144TQFP

Quantity:: RFQ Add To RFQ list

Payment:

Shipping:

Inventory:2,764

Please send an inquiry. Send us your inquiry, and we will respond immediately.

Product details

Overview

XC95144XL-10TQG144C from AMD is a CPLD orderable option aimed at deterministic control logic, decode structures, and programmable digital support functions. The device pairs 144 macrocells with nonvolatile logic retention and the 144-LQFP outline used by this orderable option, helping compact systems keep board-level logic flexible without shifting to a larger FPGA flow. This exact ordering code is typically chosen after timing, package, and qualification details are narrowed down, since 10ns-grade orderable option. together with the commercial temperature option indicated by the suffix. can materially affect fit in production hardware.

The XC9500XL family is a nonvolatile high-performance CPLD series built for low-voltage programmable logic, glue logic integration, and deterministic board-level control functions with in-system programmability. For engineers reviewing the XC95144XL-10TQG144C datasheet, XC95144XL-10TQG144C pinout, XC95144XL-10TQG144C application, or XC95144XL-10TQG144C equivalent, this device is widely used in interface glue logic, control sequencing, bus adaptation, industrial embedded modules, communications equipment, and programmable board-support designs.

Technical Context

XC95144XL-10TQG144C is intended for programmable board logic that must start in a known state, hold fixed timing behavior, and remain serviceable through in-system programming. Its 144-macrocell density is especially useful when the board needs more flexibility than discrete logic provides but does not justify a larger FPGA implementation.

The package choice is important here: 144-LQFP changes how the design team handles routing density, I/O assignment, and assembly flow, while 10ns-grade orderable option. influences how much timing margin is available for the fastest local control paths.

The XC95144XL density point is commonly used when the design needs larger control and interface logic than the smaller XC9500XL classes while still preserving CPLD-style startup determinism. In practice, this means XC95144XL-10TQG144C is often selected for local interface control, sequencing logic, and programmable control-plane functions that need CPLD-style predictability.

Key Specifications

Parameter	Value and Actual Design Meaning
Device Type	XC9500XL complex programmable logic device (CPLD).
Architecture	144-macrocell XC95144XL programmable logic architecture.
Logic Resources	144 macrocells in this device class.
Voltage Positioning	Optimized for 3.3V systems with 5V-tolerant inputs.
Timing Grade	10ns-grade orderable option.
Package	144-LQFP package with tray packing.
Operating Range	Commercial temperature option indicated by the suffix.
Programming	JTAG in-system programmability with nonvolatile logic retention.

Pinout & Package

The XC95144XL-10TQG144C pinout includes programmable user I/O, clock-capable inputs, JTAG programming pins, and dedicated supply and ground pins within 144-LQFP.

For PCB design, the main consideration is keeping high-activity I/O grouped sensibly and preserving clean clock and JTAG access on the perimeter package.

Pin / Function	PCB Design and Circuit Role
User I/O Pins	Programmable inputs and outputs for decode logic, control-state handling, and digital interface adaptation.
Clock Inputs	Clock-capable pins supporting synchronous state machines and registered logic paths.
JTAG Pins	Boundary-scan and in-system programming interface connections.
Power Pins	Supply rails supporting core and I/O operation for the selected CPLD class.
Ground Pins	Ground return paths supporting timing integrity and stable digital operation.

Key Features

144-macrocell programmable logic density supports compact board-level control integration.
Nonvolatile logic retention preserves behavior across power cycles.
JTAG in-system programmability supports manufacturing and field updates.
Deterministic CPLD timing suits glue logic, decode, and supervisory control tasks.
144-LQFP packaging supports board-specific I/O planning and dense layout integration.
Suitable for replacing multiple discrete logic functions with one programmable device.

Applications

Board Management Logic

Timing and Handshake Control

Use Scenario: Used on motherboards, daughtercards, and control modules that need local programmable management behavior.

IC Role: Implements deterministic board-support state handling.

Use Value: Supports configurable hardware behavior over product revisions.

Use Scenario: Used where local digital timing, grant signals, or handshake logic must remain predictable and programmable.

IC Role: Provides fixed-latency CPLD control for local coordination tasks.

Use Value: Improves timing confidence compared with discrete-gate chains.

Embedded Interface Concentration

Instrumentation and Service Logic

Use Scenario: Used to collect interface enables, decode conditions, and registered outputs into one programmable logic point.

IC Role: Centralizes local digital support logic around key interfaces.

Use Value: Reduces component count and eases maintenance of board logic.

Use Scenario: Used in measurement, diagnostics, and serviceable embedded hardware that needs stable programmable logic support.

IC Role: Acts as a field-updatable control and decode device.

Use Value: Helps keep hardware platforms adaptable over long deployment cycles.

Equivalent & Alternatives

When evaluating a XC95144XL-10TQG144C equivalent, engineers should compare macrocell count, package, timing grade, operating range, architecture continuity, and board-level logic-fit requirements.

Alternative Part	Technical Difference	Application Difference	Selection Advice
XC95144XL-7TQG100C	Related programmable logic option in the same or closely aligned density class with a different package, speed, or suffix emphasis.	Used when the design remains in a closely related CPLD class but the orderable fit changes.	Compare package, timing grade, operating suffix, and validated platform fit before substitution.
XC2C128-7VQG100C	Alternative CPLD solution with a different architectural position or power emphasis while serving a comparable board-support role.	Used in similar programmable control or glue-logic applications when architecture preference changes.	Choose according to logic density, power behavior, package, and family continuity requirements.

Compared with XC95144XL-7TQG100C, XC95144XL-10TQG144C selection depends on exact package, speed grade, and suffix fit within related CPLD classes. XC95144XL-10TQG144C vs XC2C128-7VQG100C selection depends on whether the design should stay with the same CPLD architecture or move to a different programmable-logic branch with other power or logic-density tradeoffs.

Quality

XC95144XL-10TQG144C should be sourced as original AMD programmable logic inventory through traceable supply channels. Quality checks may include package inspection, top-mark validation, JTAG-programming verification, and logic-image loading review.

Production validation should include timing-closure review, I/O-voltage checks, boundary-scan access, power-integrity verification, and signal-integrity assessment on high-activity control and interface nets.

Availability

XC95144XL-10TQG144C is suitable for programmable board-support logic, interface control, and deterministic CPLD integration in communications, computing, industrial, and embedded systems.

Supply support may include volume procurement planning, scheduled delivery arrangements, traceable sourcing management, and long-term supply support for OEM, industrial electronics, automotive electronics, and embedded product programs. Sample and NPI supply support, as well as urgent in-stock supply support, can also be arranged for prototype builds, pilot runs, and time-critical production needs.

For production builds, confirming package option, speed grade, operating-range suffix, lifecycle status, and sourcing continuity helps reduce programmable-logic procurement risk.

Manufacturer

AMD is a semiconductor manufacturer whose adaptive computing and programmable logic portfolio includes FPGA devices, CPLDs, configuration solutions, embedded processing platforms, and related development technologies for industrial, communication, computing, automotive, and embedded electronic systems.

The XC9500XL family is a nonvolatile high-performance CPLD series built for low-voltage programmable logic, glue logic integration, and deterministic board-level control functions with in-system programmability. The XC95144XL density point is commonly used when the design needs larger control and interface logic than the smaller XC9500XL classes while still preserving CPLD-style startup determinism.

FAQ

What is XC95144XL-10TQG144C used for?

XC95144XL-10TQG144C is used for programmable board-support logic, state sequencing, address decoding, and interface adaptation in embedded, computing, and communications hardware.

Where can I find the XC95144XL-10TQG144C datasheet download?

The XC95144XL-10TQG144C datasheet can be accessed from the confirmed source used for this CPLD family and orderable option.

What should be considered in XC95144XL-10TQG144C pinout design?

Designers should preserve JTAG access, plan I/O assignment carefully, and account for the board consequences of the 144-LQFP package and the selected timing grade.

Is XC95144XL-10TQG144C an FPGA?

No. It is a CPLD intended for deterministic programmable logic and board-control functions rather than larger FPGA fabric use.

What are common XC95144XL-10TQG144C equivalent solutions?

Common candidates include XC95144XL-7TQG100C and XC2C128-7VQG100C depending on package, architecture, logic density, and timing priorities.

XC95144XL-10TQG144C Specifications

Product attributes: Attribute value

Manufacturer:: AMD

Series:: XC9500XL

Package/Case:: 144-LQFP

Packaging:: Tray

Product Status:: Obsolete

Programmable:: Not Verified

Programmable Type:: In System Programmable (min 10K program/erase cycles)

Delay Time tpd(1) Max:: 10 ns

Voltage Supply - Internal:: 3V ~ 3.6V

Number of Logic Elements/Blocks:: 8

Number of Macrocells:: 144

Number of Gates:: 3200

Number of I/O:: 117

Operating Temperature:: 0°C ~ 70°C (TA)

Grade:: -

Qualification:: -

Mounting Type:: Surface Mount

Supplier Device Package:: 144-TQFP (20x20)

XC95144XL-10TQG144C FAQ

1.How can I place an order for XC95144XL-10TQG144C through Aetrix?

Please submit a Request for Quotation (RFQ) for XC95144XL-10TQG144C on Aetrix. Our sales agent will provide a competitive quotation and guide you through the order confirmation once you accept the terms.

2.Are the price and stock information for XC95144XL-10TQG144C reliable?

The price and inventory of XC95144XL-10TQG144C are updated periodically and may fluctuate due to market conditions. Stock and pricing data are typically refreshed every 24 hours. Quotation validity for XC95144XL-10TQG144C is usually 5 days.

3.What payment methods are accepted for XC95144XL-10TQG144C?

We accept Wire Transfer, PayPal, Credit Card, Western Union, MoneyGram, and Escrow for XC95144XL-10TQG144C transactions.

Note: Certain payment methods may incur a processing fee.

4.How is shipping managed for XC95144XL-10TQG144C?

XC95144XL-10TQG144C orders can be shipped via leading logistics carriers, including DHL, UPS, FedEx, TNT, or Registered Mail.

Once your XC95144XL-10TQG144C order is processed, you will receive an email with the shipment details and tracking number.

Note: Tracking information may take up to 24 hours to appear. Express delivery typically takes 3–5 business days.

5.How can I obtain technical support or documentation for XC95144XL-10TQG144C?

For technical support, including XC95144XL-10TQG144C datasheets, pinout diagrams, or application guidance, please contact our engineering support team. They can provide detailed documentation and assistance for your XC95144XL-10TQG144C requirements.

6.How does Aetrix verify that XC95144XL-10TQG144C is sourced from the original manufacturer or authorized distributors?

All XC95144XL-10TQG144C products on Aetrix are procured from qualified distributors and authorized channels. Our dedicated quality assurance team conducts strict verification, including traceability checks and, if necessary, third-party testing. This ensures that XC95144XL-10TQG144C meets industry standards.

7.What is the process for return or replacement of XC95144XL-10TQG144C?

All XC95144XL-10TQG144C units undergo pre-shipment inspection (PSI). If there is an issue with XC95144XL-10TQG144C, returns or replacements are accepted under the following conditions:

1.Quantity discrepancies, incorrect items, or visible external defects (such as breakage or corrosion), acknowledged by Aetrix.

2.The issue is reported within 90 days of delivery.

3.The XC95144XL-10TQG144C part is unused and in its original packaging.

Return procedure for XC95144XL-10TQG144C:

1.Submit a request within 90 days.

2.Obtain a Return Material Authorization (RMA) from Aetrix.

Tech Hub

2026-06-09 Mass Air Flow Sensor Guide: Symptoms, Cleaning, Testing, Replacement and How It Works

A mass air flow sensor, often called a MAF sensor, measures the amount of air entering an engine.

2026-06-08 Crankshaft Position Sensor Guide: Symptoms, Testing, Replacement and How It Works

A crankshaft position sensor is one of the most important engine management sensors in a modern vehicle.

2026-06-08 What Is a Decoder? Digital Logic, Decoder ICs and Electronics Applications Explained

A decoder is an electronic circuit or integrated circuit that converts a coded input into a specific output state.

2026-06-06 KG to LBS Conversion: Kilograms to Pounds Calculator

Use this kg to lbs converter to quickly convert kilograms to pounds or pounds to kilograms. It is useful for shipping weight, product specifications, package weight, material weight, equipment weight, …

2026-06-05 Analog Devices: Amplifiers, ADCs, DACs, Sensors and Power ICs Explained

Learn what analog devices are, including amplifiers, ADCs, DACs, sensors, voltage references, power ICs and ADI component selection for signal chain design.

2026-06-04 What Is SiC? Silicon Carbide Semiconductors, MOSFETs and Power Devices Explained

SiC, or silicon carbide, is a wide-bandgap semiconductor material used in high-efficiency power electronics.

2026-06-03 Type C Explained: USB-C Cable, HDMI Adapter and USB-A Compatibility Guide

Type C, more formally called USB Type-C or USB-C, is a reversible connector used for charging, data transfer, display output, and accessory connection.

2026-06-02 How to Use a Voltage Tester: AC/DC, Battery, and Voltage Divider Checks

Voltage testing is a fundamental skill for electricians, engineers, technicians, and electronics hobbyists. Accurate voltage measurement ensures safe operation, prevents equipment damage, and verifies …

2026-06-01 SR626SW Battery Equivalent: 377, AG4, LR626 and Watch Replacement Guide

Find the correct SR626SW battery equivalent, including 377, AG4 and LR626 compatibility, silver oxide vs alkaline differences, size, voltage and watch replacement checks.

2026-05-31 MLCC Ripple Current and ESR: How to Calculate Heating

MLCCs are widely used in power supply circuits, DC-DC converters, decoupling networks, RF filters, automotive modules, industrial controllers, and high-density digital hardware. Their low ESR, compact …