AMD XC9536XL-10VQG64I
- Part No.:
- XC9536XL-10VQG64I
- Manufacturer:
- AMD
- Package:
- 64-TQFP
- Datasheet:
-
XC9536XL-10VQG64I.pdf
- Description:
- IC CPLD 36MC 10NS 64VQFP
- Quantity:
- Payment:

- Shipping:

Inventory:4,649
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Product details
Overview
XC9536XL-10VQG64I from AMD is a high-performance XC9500XL CPLD built for low-voltage programmable logic, glue logic replacement, bus-interface decoding, and compact control logic functions. The device combines 36 macrocells, fast pin-to-pin timing, in-system programmability, and 5V-tolerant I/O behavior in a 64-TQFP package suited to communications, computing, and embedded board designs.
The XC9500XL CPLD series provides Fast FLASH nonvolatile programmability, Fast CONNECT II switch-matrix routing, wide function-block resources, JTAG boundary scan, and slew-rate control in compact package options. For engineers reviewing the XC9536XL-10VQG64I datasheet, XC9536XL-10VQG64I pinout, XC9536XL-10VQG64I application, or XC9536XL-10VQG64I equivalent, this device is widely used in bus interfacing, state-machine logic, address decoding, embedded control boards, communications equipment, and programmable board-support logic.
Technical Context
In embedded logic systems, XC9536XL-10VQG64I operates as a nonvolatile CPLD rather than a field-programmable processor or power device. Its 36-macrocell architecture is intended for deterministic combinational and registered logic, making it practical for decoding, timing control, chip-select generation, glue logic, and simple control-plane integration.
The XC9536XL family is optimized for 3.3V platforms while maintaining 5V-tolerant inputs, which helps it bridge legacy and newer logic rails. The 10ns-grade orderable option. timing grade and Industrial temperature option indicated by the suffix. operating-range option make this orderable part suitable for platform-specific latency and environmental targets.
XC9536XL-10VQG64I is commonly selected when a design needs predictable CPLD timing, JTAG programmability, compact package size, and board-level logic retention without the complexity of a larger FPGA platform.
Key Specifications
| Parameter | Value and Actual Design Meaning |
|---|---|
| Device Type | High-performance in-system programmable CPLD. |
| Architecture | 36 macrocells with about 800 usable gates in the XC9500XL architecture. |
| Core / I/O Voltage | Optimized for 3.3V systems with 5V-tolerant input capability. |
| Timing Grade | 10ns-grade orderable option. |
| System Capability | Fast CPLD logic for decoding, control, and board-support functions. |
| Package | 64-TQFP |
| Operating Range | Industrial temperature option indicated by the suffix. |
| Design Features | JTAG boundary scan, Fast CONNECT II routing, slew-rate control, and enhanced data security. |
Pinout & Package
The XC9536XL-10VQG64I pinout is organized around programmable I/O pins, global clocks, JTAG programming and test pins, dedicated power rails, and ground return connections within the 64-TQFP outline.
For PCB design, designers typically group high-activity I/O by function block where possible, keep JTAG access available, and maintain clean 3.3V decoupling near the CPLD power pins to support timing integrity.
| Pin / Function | PCB Design and Circuit Role |
|---|---|
| User I/O Pins | Programmable logic inputs and outputs for decoding, control, and registered logic functions. |
| Global Clock Pins | Dedicated clock-capable inputs for synchronous CPLD timing paths. |
| JTAG Pins | IEEE 1149.1 boundary-scan and in-system programming interface connections. |
| Output Enable / Control Terms | Internal product-term controlled output behavior for board-level interface logic. |
| VCCINT / VCCIO | 3.3V supply pins supporting CPLD core and I/O operation. |
| GND | Low-impedance return path supporting timing and signal integrity. |
Key Features
- 36-macrocell CPLD architecture supports compact programmable control logic.
- 3.3V system optimization with 5V-tolerant inputs eases mixed-voltage interfacing.
- Fast FLASH nonvolatile configuration retains logic at power cycle.
- JTAG boundary scan supports in-system programming and board test.
- Fast CONNECT II routing improves pin-locking and routability.
- Compact package suits dense embedded and communications boards.
Applications
| Address Decoding and Glue Logic | State-Machine Control |
|---|---|
|
Use Scenario: Used in boards that need chip selects, bus decoding, and peripheral logic around processors or ASICs. IC Role: Implements deterministic board-support logic with nonvolatile retention. Use Value: Reduces discrete logic count and simplifies board updates. |
Use Scenario: Used in embedded subsystems that need compact programmable control sequencing. IC Role: Provides registered logic and control-term driven state handling. Use Value: Improves flexibility without moving to a larger FPGA. |
| Communications and Computing Boards | Legacy-to-3.3V Interface Support |
|
Use Scenario: Used in interface, timing, and supervisory logic on networking or computing hardware. IC Role: Bridges logic domains and implements local control logic. Use Value: Supports compact logic integration with predictable timing. |
Use Scenario: Used where 5V-tolerant inputs must coexist with 3.3V programmable logic. IC Role: Accepts higher-voltage input signaling while operating in low-voltage systems. Use Value: Helps preserve compatibility in mixed-voltage platforms. |
Equivalent & Alternatives
When evaluating a XC9536XL-10VQG64I equivalent, engineers should compare macrocell count, timing grade, package, operating temperature option, voltage compatibility, and JTAG programmability.
| Alternative Part | Technical Difference | Application Difference | Selection Advice |
|---|---|---|---|
| XC9536XL-7VQG44C | Same XC9536XL family with a different speed or temperature suffix depending on platform requirement. | Used in the same CPLD logic class when the package and macrocell count match. | Compare exact speed grade, environmental range, and approved assembly flow. |
| XC2C32A-6VQG44C | CoolRunner-II CPLD with a newer low-power architecture and 32 macrocells rather than the XC9500XL structure. | Used in similar board-support logic roles where lower standby current and CoolRunner-II architecture are acceptable. | Choose according to macrocell resources, supply rail, timing, and legacy design compatibility. |
Compared with XC9536XL-7VQG44C, XC9536XL-10VQG64I selection depends on the exact suffix-defined timing and temperature option for the target board. XC9536XL-10VQG64I vs XC2C32A-6VQG44C selection depends on whether the design should stay within the XC9500XL architecture or move to a CoolRunner-II CPLD with different power and logic characteristics.
Quality
XC9536XL-10VQG64I should be sourced as original AMD programmable logic inventory through traceable supply channels. Quality checks may include package inspection, top-mark validation, solderability review, and JTAG-programming verification of the CPLD image.
Production validation should include I/O timing checks, boundary-scan access, voltage-rail integrity, logic fit verification, and signal-integrity review for the highest-activity interface pins.
Availability
XC9536XL-10VQG64I is suitable for embedded logic, communications, and board-support applications requiring XC9500XL-class CPLD functionality in a compact package.
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.
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.
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.
FAQ
What is XC9536XL-10VQG64I used for?
XC9536XL-10VQG64I is used for address decoding, programmable glue logic, state-machine control, and board-support logic in communications, computing, and embedded systems.
Where can I find the XC9536XL-10VQG64I datasheet download?
The XC9536XL-10VQG64I datasheet can be accessed from the Mouser product page and documents area for this AMD/Xilinx programmable logic device.
What should be considered in XC9536XL-10VQG64I pinout design?
Designers should reserve JTAG access, decouple the 3.3V supply well, manage high-activity I/O placement, and verify the chosen speed and temperature suffix against the board timing budget.
Is XC9536XL-10VQG64I an FPGA?
No. It is a CPLD in the XC9500XL family, intended for deterministic programmable logic and board-support functions rather than larger FPGA fabric use.
What are common XC9536XL-10VQG64I equivalent solutions?
Common candidates include XC9536XL-7VQG44C and XC2C32A-6VQG44C depending on architecture, timing, package, and power requirements.
XC9536XL-10VQG64I Specifications
- Product attributes
- Attribute value
- Manufacturer:
- AMD
- Series:
- XC9500XL
- Package/Case:
- 64-TQFP
- Packaging:
- Tray
- Product Status:
- Obsolete
- Programmable:
- 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:
- 2
- Number of Macrocells:
- 36
- Number of Gates:
- 800
- Number of I/O:
- 36
- Operating Temperature:
- -40°C ~ 85°C (TA)
- Grade:
- -
- Qualification:
- -
- Mounting Type:
- Surface Mount
- Supplier Device Package:
- 64-VQFP (10x10)
XC9536XL-10VQG64I FAQ
1.How can I place an order for XC9536XL-10VQG64I through Aetrix?
Please submit a Request for Quotation (RFQ) for XC9536XL-10VQG64I 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 XC9536XL-10VQG64I reliable?
The price and inventory of XC9536XL-10VQG64I are updated periodically and may fluctuate due to market conditions. Stock and pricing data are typically refreshed every 24 hours. Quotation validity for XC9536XL-10VQG64I is usually 5 days.
3.What payment methods are accepted for XC9536XL-10VQG64I?
We accept Wire Transfer, PayPal, Credit Card, Western Union, MoneyGram, and Escrow for XC9536XL-10VQG64I transactions.
Note: Certain payment methods may incur a processing fee.
4.How is shipping managed for XC9536XL-10VQG64I?
XC9536XL-10VQG64I orders can be shipped via leading logistics carriers, including DHL, UPS, FedEx, TNT, or Registered Mail.
Once your XC9536XL-10VQG64I 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 XC9536XL-10VQG64I?
For technical support, including XC9536XL-10VQG64I datasheets, pinout diagrams, or application guidance, please contact our engineering support team. They can provide detailed documentation and assistance for your XC9536XL-10VQG64I requirements.
6.How does Aetrix verify that XC9536XL-10VQG64I is sourced from the original manufacturer or authorized distributors?
All XC9536XL-10VQG64I 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 XC9536XL-10VQG64I meets industry standards.
7.What is the process for return or replacement of XC9536XL-10VQG64I?
All XC9536XL-10VQG64I units undergo pre-shipment inspection (PSI). If there is an issue with XC9536XL-10VQG64I, 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 XC9536XL-10VQG64I part is unused and in its original packaging.
Return procedure for XC9536XL-10VQG64I:
1.Submit a request within 90 days.
2.Obtain a Return Material Authorization (RMA) from Aetrix.
XC9536XL-10VQG64I Tags

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5M40ZE64C5N
Intel

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ATF1502ASV-15AU44
Microchip Technology

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5M80ZE64C5N
Intel

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5M80ZT100C5N
Intel

-
ATF1502AS-10AU44
Microchip Technology

-
ATF1502AS-10JU44
Microchip Technology

-
5M80ZE64I5N
Intel

-
5M80ZT100I5N
Intel
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LC4032V-75TN48C
Lattice Semiconductor Corporation

-
ATF1504ASV-15AU44
Microchip Technology

-
ATF1504AS-10JU44
Microchip Technology

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5M160ZE64C5N
Intel
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