AMD XC2C128-7TQG144I
- Part No.:
- XC2C128-7TQG144I
- Manufacturer:
- AMD
- Package:
- 144-LQFP
- Datasheet:
-
XC2C128-7TQG144I.pdf
- Description:
- IC CPLD 128MC 7NS 144TQFP
- Quantity:
- Payment:

- Shipping:

Inventory:4,332
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Product details
Overview
XC2C128-7TQG144I from AMD is a CoolRunner-II CPLD intended for low-power programmable logic, interface consolidation, control sequencing, and higher-density board-support logic in embedded and communications hardware. The device combines 128 macrocells, very low standby-current architecture, fast CPLD timing, and multi-voltage I/O support in a 144-LQFP package for denser programmable-control tasks than the 64-macrocell class.
The CoolRunner-II CPLD series provides nonvolatile logic retention, JTAG-based in-system programmability, low-power architecture, and compact macrocell resources for control and interface functions. For engineers reviewing the XC2C128-7TQG144I datasheet, XC2C128-7TQG144I pinout, XC2C128-7TQG144I application, or XC2C128-7TQG144I equivalent, this device is widely used in interface glue logic, portable embedded systems, control-plane logic, bus adaptation, industrial modules, and low-power programmable board-support designs.
Technical Context
In embedded systems, XC2C128-7TQG144I serves as a compact CPLD for moderate-to-high density deterministic logic tasks such as state sequencing, bus adaptation, decode structures, and local supervisory logic. Its 128-macrocell resource level is valuable when the design needs more headroom than 64-macrocell CPLDs but still benefits from CPLD-style nonvolatile startup and low standby current.
CoolRunner-II devices are valued for very low standby current and fast timing, which makes them useful in portable, battery-aware, or thermally constrained platforms. The selected 7ns-grade orderable option. and Industrial temperature option indicated by the suffix. option also matters because the exact speed and environmental range often drive fit decisions for field-programmable board-support logic.
XC2C128-7TQG144I is commonly selected when a design needs compact programmable logic, JTAG programmability, and stable low-power operation in a package tailored to the board's I/O density and environmental target.
Key Specifications
| Parameter | Value and Actual Design Meaning |
|---|---|
| Device Type | Low-power CoolRunner-II CPLD. |
| Architecture | 128-macrocell programmable logic architecture. |
| Timing | 7ns-grade orderable option. |
| Power Behavior | Very low quiescent-current CoolRunner-II architecture for always-on logic roles. |
| I/O Support | Multi-voltage I/O operation across common 1.5V to 3.3V logic domains. |
| Package | 144-LQFP |
| Operating Range | Industrial temperature option indicated by the suffix. |
| Programming | JTAG in-system programmability with nonvolatile logic retention. |
Pinout & Package
The XC2C128-7TQG144I pinout includes programmable I/O grouped across banked logic resources, JTAG programming pins, clock-capable inputs, supply rails, and ground returns in the 144-LQFP outline.
For PCB design, bank voltage planning, JTAG access, and quiet local decoupling are important because CoolRunner-II devices are often used between different logic domains and as always-on supervisory logic.
| Pin / Function | PCB Design and Circuit Role |
|---|---|
| User I/O Pins | Programmable inputs and outputs for logic interfacing, decoding, and control-state implementation. |
| Clock Inputs | Clock-capable pins supporting synchronous logic and internal macrocell timing. |
| JTAG Pins | IEEE 1149.1 and IEEE 1532 style in-system programming and test access. |
| I/O Bank Supplies | Voltage domains supporting multi-voltage interfacing across logic banks. |
| Core Supply | Low-voltage CPLD core supply supporting low-power operation. |
| GND | Ground reference and return path for logic stability and programming integrity. |
Key Features
- 128 macrocells provide higher CPLD logic density than smaller CoolRunner-II devices.
- Very low standby current suits portable and always-on logic roles.
- Fast pin-to-pin delays support interface and control timing closure.
- Multi-voltage I/O compatibility eases logic-domain bridging.
- JTAG in-system programmability simplifies production and field updates.
- Compact packages fit dense embedded hardware layouts.
Applications
| Portable Embedded Systems | Bus and Interface Adaptation |
|---|---|
|
Use Scenario: Used in battery-powered or space-constrained products that need small programmable logic blocks. IC Role: Implements always-on control and interface logic with low standby current. Use Value: Supports low-power operation without a larger FPGA. |
Use Scenario: Used between processors, peripherals, and legacy digital logic. IC Role: Handles glue logic, decoding, and control translation across mixed-voltage domains. Use Value: Reduces discrete logic and improves integration. |
| Industrial Modules | Communications Equipment |
|
Use Scenario: Used in I/O cards, local control boards, and supervisory logic planes. IC Role: Provides deterministic CPLD logic for sequencing, gating, and control. Use Value: Improves reliability and field programmability. |
Use Scenario: Used in small control-plane logic blocks on communications boards. IC Role: Supports timing, enable, and local interface logic. Use Value: Preserves programmable flexibility in compact board areas. |
Equivalent & Alternatives
When evaluating a XC2C128-7TQG144I equivalent, engineers should compare macrocell count, package, timing, voltage-bank compatibility, standby current, and temperature option.
| Alternative Part | Technical Difference | Application Difference | Selection Advice |
|---|---|---|---|
| XC2C32A-6VQG44C | Same CoolRunner-II family with a different package and timing suffix within the same macrocell class. | Used when the board can accept the same logic class with a different package or speed option. | Compare exact package, speed, and environmental suffix before substitution. |
| XC9536XL-10VQG44C | XC9500XL CPLD with a different architecture and power profile but a similar board-support logic role. | Used in comparable glue-logic and control tasks where legacy XC9500XL fit is preferred. | Choose according to standby current, architecture preference, logic fit, and voltage strategy. |
Compared with XC2C32A-6VQG44C, XC2C128-7TQG144I selection depends on the exact package, speed, and temperature suffix required by the board build. XC2C128-7TQG144I vs XC9536XL-10VQG44C selection depends on whether the design prioritizes CoolRunner-II low-power behavior or XC9500XL legacy CPLD architecture.
Quality
XC2C128-7TQG144I should be sourced as original AMD programmable logic inventory through traceable channels. Quality checks may include package inspection, top-mark validation, JTAG programming verification, and logic-image loading tests.
Production validation should include bank-voltage compatibility, boundary-scan access, logic timing, standby-current expectations, and signal-integrity review on high-speed control or interface pins.
Availability
XC2C128-7TQG144I is suitable for low-power programmable logic, board-support functions, and compact CPLD integration in embedded and communications designs.
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 CoolRunner-II family is a low-power nonvolatile CPLD series designed for compact programmable logic, interface adaptation, and always-on control functions with very low standby current and multi-voltage I/O support.
FAQ
What is XC2C128-7TQG144I used for?
XC2C128-7TQG144I is used for low-power glue logic, state-machine control, bus adaptation, and compact programmable logic in embedded, communications, and industrial systems.
Where can I find the XC2C128-7TQG144I datasheet download?
The XC2C128-7TQG144I datasheet can be accessed from the Mouser product page and documents area for this AMD/Xilinx CoolRunner-II CPLD.
What should be considered in XC2C128-7TQG144I pinout design?
Designers should plan I/O-bank voltages carefully, preserve JTAG access, decouple local supplies, and align the chosen package and speed suffix with the target board requirements.
Is XC2C128-7TQG144I an FPGA?
No. It is a CoolRunner-II CPLD intended for compact programmable logic and control functions rather than larger FPGA fabric use.
What are common XC2C128-7TQG144I equivalent solutions?
Common candidates include XC2C32A-6VQG44C and XC9536XL-10VQG44C depending on package, architecture, power target, and timing requirements.
XC2C128-7TQG144I Specifications
- Product attributes
- Attribute value
- Manufacturer:
- AMD
- Series:
- CoolRunner II
- Package/Case:
- 144-LQFP
- Packaging:
- Tray
- Product Status:
- Obsolete
- Programmable:
- Not Verified
- Programmable Type:
- In System Programmable
- Delay Time tpd(1) Max:
- 7 ns
- Voltage Supply - Internal:
- 1.7V ~ 1.9V
- Number of Logic Elements/Blocks:
- 8
- Number of Macrocells:
- 128
- Number of Gates:
- 3000
- Number of I/O:
- 100
- Operating Temperature:
- -40°C ~ 85°C (TA)
- Grade:
- -
- Qualification:
- -
- Mounting Type:
- Surface Mount
- Supplier Device Package:
- 144-TQFP (20x20)
XC2C128-7TQG144I FAQ
1.How can I place an order for XC2C128-7TQG144I through Aetrix?
Please submit a Request for Quotation (RFQ) for XC2C128-7TQG144I 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 XC2C128-7TQG144I reliable?
The price and inventory of XC2C128-7TQG144I are updated periodically and may fluctuate due to market conditions. Stock and pricing data are typically refreshed every 24 hours. Quotation validity for XC2C128-7TQG144I is usually 5 days.
3.What payment methods are accepted for XC2C128-7TQG144I?
We accept Wire Transfer, PayPal, Credit Card, Western Union, MoneyGram, and Escrow for XC2C128-7TQG144I transactions.
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XC2C128-7TQG144I orders can be shipped via leading logistics carriers, including DHL, UPS, FedEx, TNT, or Registered Mail.
Once your XC2C128-7TQG144I 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 XC2C128-7TQG144I?
For technical support, including XC2C128-7TQG144I datasheets, pinout diagrams, or application guidance, please contact our engineering support team. They can provide detailed documentation and assistance for your XC2C128-7TQG144I requirements.
6.How does Aetrix verify that XC2C128-7TQG144I is sourced from the original manufacturer or authorized distributors?
All XC2C128-7TQG144I 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 XC2C128-7TQG144I meets industry standards.
7.What is the process for return or replacement of XC2C128-7TQG144I?
All XC2C128-7TQG144I units undergo pre-shipment inspection (PSI). If there is an issue with XC2C128-7TQG144I, 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 XC2C128-7TQG144I part is unused and in its original packaging.
Return procedure for XC2C128-7TQG144I:
1.Submit a request within 90 days.
2.Obtain a Return Material Authorization (RMA) from Aetrix.
XC2C128-7TQG144I Tags

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5M40ZE64C5N
Intel

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ATF1502ASV-15AU44
Microchip Technology

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Intel

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5M80ZT100C5N
Intel

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ATF1502AS-10AU44
Microchip Technology

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ATF1502AS-10JU44
Microchip Technology

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5M80ZE64I5N
Intel

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5M80ZT100I5N
Intel
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LC4032V-75TN48C
Lattice Semiconductor Corporation

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Microchip Technology

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Microchip Technology

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Intel
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