AMD XC2C384-10TQG144C
- Part No.:
- XC2C384-10TQG144C
- Manufacturer:
- AMD
- Package:
- 144-LQFP
- Datasheet:
-
XC2C384-10TQG144C.pdf
- Description:
- IC CPLD 384MC 9.2NS 144TQFP
- Quantity:
- Payment:

- Shipping:

Inventory:8,273
Please send an inquiry. Send us your inquiry, and we will respond immediately.
Product details
Overview
XC2C384-10TQG144C from AMD is a CoolRunner-II CPLD intended for low-power programmable logic, interface consolidation, and very high-density board-support logic in embedded and communications hardware. The device combines 384 macrocells, very low standby-current architecture, fast CPLD timing, and multi-voltage I/O support in a 144-LQFP package for designs that need more programmable logic density than the 256-macrocell class.
The CoolRunner-II CPLD series provides nonvolatile logic retention, JTAG-based in-system programmability, low-power architecture, and scalable macrocell resources for compact control and interface functions. For engineers reviewing the XC2C384-10TQG144C datasheet, XC2C384-10TQG144C pinout, XC2C384-10TQG144C application, or XC2C384-10TQG144C equivalent, this device is widely used in control-plane logic, protocol adaptation, industrial modules, communications boards, bus interfacing, and low-power programmable board-support designs.
Technical Context
In embedded systems, XC2C384-10TQG144C serves as a compact CPLD for very high-density deterministic logic tasks such as state sequencing, protocol adaptation, bus consolidation, and local supervisory logic. Its 384-macrocell resource level is useful when the design needs more headroom than medium-density CPLDs but still benefits from nonvolatile CPLD startup behavior and low standby current.
CoolRunner-II devices remain attractive where standby current matters, because the family is designed for low-power always-on logic roles. At this density, the architecture allows one CPLD to consolidate very large amounts of board-control and interface logic while still remaining simpler than a larger FPGA flow.
XC2C384-10TQG144C is commonly used when a board needs compact programmable logic with very high macrocell density, low standby-current behavior, JTAG updateability, and deterministic control or interface timing.
Key Specifications
| Parameter | Value and Actual Design Meaning |
|---|---|
| Device Type | Low-power CoolRunner-II CPLD. |
| Architecture | 384-macrocell programmable logic architecture. |
| Power Behavior | Low standby-current CPLD architecture for always-on control and interface roles. |
| Timing Grade | 10ns-grade orderable option indicated by the part suffix. |
| I/O Support | Multi-voltage I/O operation across common low-voltage logic domains. |
| 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 XC2C384-10TQG144C pinout includes large programmable I/O resources, clock-capable pins, JTAG interface pins, supply rails, and ground returns in the 144-LQFP outline.
For PCB design, I/O-bank planning, JTAG access, and supply decoupling are important because XC2C384 devices are often used as central programmable control elements between several logic domains.
| Pin / Function | PCB Design and Circuit Role |
|---|---|
| User I/O Pins | Programmable logic I/O used for decode, control, interface adaptation, and registered logic functions. |
| Clock Inputs | Clock-capable pins supporting synchronous CPLD timing structures. |
| JTAG Pins | In-system programming and boundary-scan access connections. |
| I/O Bank Supplies | Support the voltage strategy for interfacing with external logic domains. |
| Core Supply | Low-voltage internal logic supply for CPLD operation. |
| GND | Ground return path supporting logic stability and programming integrity. |
Key Features
- 384 macrocells provide very high CPLD logic density for board-support integration.
- Very low standby current suits always-on and portable logic functions.
- Nonvolatile CPLD operation preserves logic at power cycle.
- JTAG in-system programmability supports production and field updates.
- Mixed-voltage I/O support eases logic-domain bridging.
- Package options fit dense embedded and communications layouts.
Applications
| Control-Plane Logic | Protocol and Bus Adaptation |
|---|---|
|
Use Scenario: Used in embedded boards for local sequencing, control, and supervisory logic with very high macrocell demand. IC Role: Implements deterministic programmable control behavior. Use Value: Improves updateability without moving to a larger FPGA. |
Use Scenario: Used between processors, peripherals, and digital interfaces requiring very dense programmable logic. IC Role: Performs glue logic, decode, and control translation. Use Value: Reduces discrete logic and preserves flexibility. |
| Industrial Modules | Communications Boards |
|
Use Scenario: Used in control, instrumentation, and I/O modules requiring very high CPLD density. IC Role: Supplies board-support logic with low standby-current behavior. Use Value: Supports compact and reliable field-programmable logic. |
Use Scenario: Used in communications hardware for very large local interface and control-plane functions. IC Role: Provides low-power programmable logic near digital interfaces. Use Value: Supports scalable board integration with deterministic timing. |
Equivalent & Alternatives
When evaluating a XC2C384-10TQG144C equivalent, engineers should compare macrocell count, package, low-power behavior, timing grade, and logic-domain compatibility.
| Alternative Part | Technical Difference | Application Difference | Selection Advice |
|---|---|---|---|
| XC2C256-7TQG144C | Smaller CoolRunner-II family member with lower macrocell count and a similar architectural style. | Used when the board logic requirement is lower and can fit into a smaller CPLD density point. | Compare macrocell fit, timing, package, and logic margin. |
| XC95288XL-10TQG144C | XC9500XL CPLD with a different architecture but a comparable very high-density board-support logic role. | Used in dense CPLD control and glue-logic applications when XC9500XL architecture is preferred. | Choose according to power target, architecture continuity, and logic-fit behavior. |
Compared with XC2C256-7TQG144C, XC2C384-10TQG144C is better suited when the design needs significantly more macrocell density while remaining in the CoolRunner-II family. XC2C384-10TQG144C vs XC95288XL-10TQG144C selection depends on whether the design should prioritize CoolRunner-II low-power behavior or maintain XC9500XL architectural continuity at high density.
Quality
XC2C384-10TQG144C 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, timing closure, standby-current expectations, boundary-scan access, and signal-integrity review on high-activity control pins.
Availability
XC2C384-10TQG144C is suitable for low-power programmable board-support logic, interface adaptation, and very high-density CPLD integration in embedded and communications 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.
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 XC2C384-10TQG144C used for?
XC2C384-10TQG144C is used for low-power programmable glue logic, protocol adaptation, state-machine control, and very high-density CPLD board-support functions.
Where can I find the XC2C384-10TQG144C datasheet download?
The XC2C384-10TQG144C datasheet can be accessed from the Mouser product page and documents area for this AMD/Xilinx CoolRunner-II CPLD.
What should be considered in XC2C384-10TQG144C pinout design?
Designers should plan bank voltages, preserve JTAG access, and align the chosen package with the board's I/O density and environmental constraints.
Is XC2C384-10TQG144C an FPGA?
No. It is a CoolRunner-II CPLD intended for compact deterministic programmable logic and control functions.
What are common XC2C384-10TQG144C equivalent solutions?
Common candidates include XC2C256-7TQG144C and XC95288XL-10TQG144C depending on package, architecture, and power requirements.
XC2C384-10TQG144C 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:
- 9.2 ns
- Voltage Supply - Internal:
- 1.7V ~ 1.9V
- Number of Logic Elements/Blocks:
- 24
- Number of Macrocells:
- 384
- Number of Gates:
- 9000
- Number of I/O:
- 118
- Operating Temperature:
- 0°C ~ 70°C (TA)
- Grade:
- -
- Qualification:
- -
- Mounting Type:
- Surface Mount
- Supplier Device Package:
- 144-TQFP (20x20)
XC2C384-10TQG144C FAQ
1.How can I place an order for XC2C384-10TQG144C through Aetrix?
Please submit a Request for Quotation (RFQ) for XC2C384-10TQG144C 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 XC2C384-10TQG144C reliable?
The price and inventory of XC2C384-10TQG144C are updated periodically and may fluctuate due to market conditions. Stock and pricing data are typically refreshed every 24 hours. Quotation validity for XC2C384-10TQG144C is usually 5 days.
3.What payment methods are accepted for XC2C384-10TQG144C?
We accept Wire Transfer, PayPal, Credit Card, Western Union, MoneyGram, and Escrow for XC2C384-10TQG144C transactions.
Note: Certain payment methods may incur a processing fee.
4.How is shipping managed for XC2C384-10TQG144C?
XC2C384-10TQG144C orders can be shipped via leading logistics carriers, including DHL, UPS, FedEx, TNT, or Registered Mail.
Once your XC2C384-10TQG144C 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 XC2C384-10TQG144C?
For technical support, including XC2C384-10TQG144C datasheets, pinout diagrams, or application guidance, please contact our engineering support team. They can provide detailed documentation and assistance for your XC2C384-10TQG144C requirements.
6.How does Aetrix verify that XC2C384-10TQG144C is sourced from the original manufacturer or authorized distributors?
All XC2C384-10TQG144C 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 XC2C384-10TQG144C meets industry standards.
7.What is the process for return or replacement of XC2C384-10TQG144C?
All XC2C384-10TQG144C units undergo pre-shipment inspection (PSI). If there is an issue with XC2C384-10TQG144C, 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 XC2C384-10TQG144C part is unused and in its original packaging.
Return procedure for XC2C384-10TQG144C:
1.Submit a request within 90 days.
2.Obtain a Return Material Authorization (RMA) from Aetrix.
XC2C384-10TQG144C Tags

-
5M40ZE64C5N
Intel

-
ATF1502ASV-15AU44
Microchip Technology

-
5M80ZE64C5N
Intel

-
5M80ZT100C5N
Intel

-
ATF1502AS-10AU44
Microchip Technology

-
ATF1502AS-10JU44
Microchip Technology

-
5M80ZE64I5N
Intel

-
5M80ZT100I5N
Intel
-
LC4032V-75TN48C
Lattice Semiconductor Corporation

-
ATF1504ASV-15AU44
Microchip Technology

-
ATF1504AS-10JU44
Microchip Technology

-
5M160ZE64C5N
Intel
Tech Hub
Amplifier guide covering voltage, current and power amplification, gain, feedback, amplifier classes, audio and RF applications, op-amp circuits, transimpedance amplifiers, datasheet selection and trou…
Machine vision system guide covering components, inspection workflow, camera and lens selection, FOV, pixel resolution, motion blur, strobe lighting, bandwidth, 2D/3D vision, integration, troubleshooti…
Electronic devices and circuits guide covering passive components, semiconductors, analog and digital circuits, circuit theory, practical calculations, troubleshooting, datasheet selection, and learnin…
Oil pressure sensor diagnosis covering symptoms, location, testing, replacement, socket access, common failure cases, and the electronic signal path between the pressure sensor, wiring, ECU and gauge s…
MLCC ESR, impedance and self-resonant frequency in decoupling networks. Covers PDN behavior, frequency response, measurement methods, failure cases and practical capacitor selection for power integrity…
An actuator converts a control signal and energy source into mechanical motion. This guide explains actuator types, working principles, electric and linear actuators, automotive use cases, troubleshoot…
A potentiometer is a three-terminal adjustable resistor used for voltage division, analog control, calibration and signal adjustment. This guide explains wiring, symbols, types, 10k values, digital pot…
An FPGA is reconfigurable digital hardware used for custom logic, parallel processing, low-latency I/O and interface control. This guide explains FPGA meaning, architecture, boards, programming flow, a…
A logic gate is a basic digital circuit that uses Boolean logic to convert binary inputs into one output. This guide explains AND, OR, NOT, NAND, NOR, XOR, truth tables, universal gates, logic ICs and …
A mass air flow sensor, often called a MAF sensor, measures the amount of air entering an engine.

