Espressif Systems ESP32-C3FH4X
- Part No.:
- ESP32-C3FH4X
- Manufacturer:
- Espressif Systems
- Category:
- RF Transceiver ICs
- Package:
- 32-VFQFN Exposed Pad
- Datasheet:
-
ESP32-C3FH4X.pdf
- Description:
- ESP32-C3FH4X IS AN LOW-POWER AND
- Quantity:
- Payment:

- Shipping:

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Product details
Overview
ESP32-C3FH4X from Espressif Systems is a ultra-low-power RISC-V SoC with 2.4 GHz Wi-Fi and Bluetooth LE intended for embedded wireless control, protocol processing, sensor acquisition, and connected-device firmware execution.
Designed for low-power IoT devices, wireless sensors, smart plugs, BLE provisioning nodes, industrial endpoints, asset tags, and compact Wi-Fi/BLE modules, the ESP32-C3FH4X fits systems that require embedded wireless connectivity, deterministic control, software-defined peripheral assignment, and compact production hardware. Compared with simple radio modules, Espressif devices usually combine MCU execution, RF connectivity, security blocks, power management, and SDK support within one chip or module family.
The ESP32-C3 platform provides 32-bit RISC-V single-core processor operating up to 160 MHz, 2.4 GHz 802.11 b/g/n Wi-Fi and Bluetooth 5 Low Energy with Bluetooth mesh support, 384 KB ROM, 400 KB SRAM with 16 KB used for cache, 8 KB RTC SRAM, and optional in-package flash depending on the exact chip variant, and up to 22 programmable GPIOs depending on variant, UART, SPI, I2C, I2S, USB Serial/JTAG, TWAI, LED PWM, RMT, ADC, temperature sensor, timers, and watchdogs. For engineers evaluating the ESP32-C3FH4X datasheet, ESP32-C3FH4X pinout, ESP32-C3FH4X application, or ESP32-C3FH4X equivalent, the device should be selected by matching wireless protocol, memory size, antenna path, GPIO count, package footprint, security requirements, and software ecosystem support.
Technical Context
In a custom embedded design, ESP32-C3FH4X is used as a bare Espressif SoC from the ESP32-C3 platform. Unlike a certified module, the SoC requires the designer to implement power supply filtering, RF matching, crystal circuitry, flash or PSRAM connection where applicable, boot strapping, antenna layout, and production programming access on the final PCB.
The device platform provides single-core 32-bit RISC-V processor up to 160 MHz and 2.4 GHz Wi-Fi 4 and Bluetooth 5 Low Energy. Memory resources are memory configuration defined by the exact Espressif orderable suffix; when the part number indicates embedded flash or PSRAM, firmware partitioning, OTA update capacity, and runtime buffering should be matched to that exact ordering option.
Hardware design should verify 3.3V rail stability, RF trace impedance, antenna matching, boot pin states, reset timing, flash/PSRAM signal integrity, crystal loading, thermal behavior, and access to UART, USB serial/JTAG, or JTAG programming depending on the family. SoC-level selection provides the most layout flexibility but also requires the full Espressif reference-design discipline during production design.
Key Specifications
| Parameter | Value and Actual Design Meaning |
|---|---|
| Product Type | Wireless MCU SoC from the ESP32-C3 platform. |
| CPU Architecture | single-core 32-bit RISC-V processor up to 160 MHz. |
| Wireless Connectivity | 2.4 GHz Wi-Fi 4 and Bluetooth 5 Low Energy. |
| Memory Configuration | memory configuration defined by the exact Espressif orderable suffix. |
| Peripheral Resources | SPI, I2C, I2S, UART, RMT, LED PWM, ADC, temperature sensor, timers, USB serial/JTAG on supported variants, and GPIO matrix. |
| Security Resources | secure boot, flash encryption, cryptographic acceleration, RNG, HMAC, digital signature, and secure device identity resources. |
| Hardware Design Meaning | Requires custom RF, clock, flash/PSRAM, power, boot strapping, programming, and antenna layout implementation on the final PCB. |
| Production Selection Meaning | Best suited where the designer needs full control of RF layout, module form factor, cost structure, and board-level integration. |
Pinout & Package
ESP32-C3FH4X is a chip-level implementation of the ESP32-C3 RISC-V Wi-Fi and Bluetooth LE platform. Its pinout must be planned around RF matching, power-domain decoupling, boot-mode pins, flash or PSRAM interface requirements, programming/debug access, and the GPIO matrix used to assign serial, analog, timing, and control peripherals.
Flash option indicated by the order code: 4 MB in-package flash option. For chip-level PCB design, the RF path and crystal area should be isolated from noisy digital and switching-power sections, while EN, boot strapping, download, and debug pins should remain accessible for manufacturing and firmware recovery.
| Pin / Function | PCB Design and Circuit Role |
|---|---|
| RF / Antenna Path | The 2.4 GHz Wi-Fi and Bluetooth LE RF path requires antenna keep-out, controlled routing, and a low-noise ground environment. |
| USB Serial/JTAG or UART Download Pins | Programming and debug access should be preserved through the device-supported USB Serial/JTAG or UART download path. |
| GPIO / Peripheral Pins | GPIO planning should include SPI, UART, I2C, LED PWM, ADC, timers, and low-power wake behavior available on the selected package. |
| Boot / Strapping Pins | Boot-mode pins need stable pull states at reset and should not be disturbed by external loads. |
| Power and Ground Pins | Local bypass capacitors, short ground returns, and clean RF/digital supply routing improve boot stability and wireless performance. |
Key Features
- ESP32-C3 platform integration: combines MCU processing, wireless connectivity, memory architecture, and peripheral routing in a single Espressif ecosystem device.
- Wireless protocol coverage: 2.4 GHz 802.11 b/g/n Wi-Fi and Bluetooth 5 Low Energy with Bluetooth mesh support.
- Embedded software support: suitable for ESP-IDF-based firmware development, OTA workflows, provisioning, networking stacks, and security configuration.
- Hardware integration focus: RF layout, power integrity, boot strapping, flash/PSRAM selection, and antenna design should be validated against the Espressif reference material.
- Production suitability: modules and DevKits simplify evaluation, while SoC-level variants support custom PCB designs requiring full RF and power-layout control.
- Security and lifecycle value: secure boot, flash encryption, cryptographic accelerators, and device identity features help support connected-product deployment.
Applications
| ESP32-C3 Custom SoC Designs | RF and Antenna Controlled Layouts |
|---|---|
|
Use Scenario: smart plugs, light controls, compact sensors, BLE-provisioned Wi-Fi devices, cloud-connected controllers, and low-cost IoT nodes IC Role: ESP32-C3FH4X acts as the main SoC for products requiring custom RF, power, memory, and peripheral implementation. Use Value: Provides a compact risc-v wi-fi/ble mcu platform with security features for cost-sensitive connected devices. |
Use Scenario: Custom antenna designs, compact modules, unique enclosure layouts, and high-volume board designs. IC Role: The SoC gives the designer full control of RF matching, antenna selection, and board-level layout. Use Value: Useful when module size, cost, or antenna architecture does not match the product requirement. |
| Embedded Control and Connectivity | Cost-Optimized Production Hardware |
|
Use Scenario: Sensors, relays, displays, audio interfaces, low-power monitors, local logic, and protocol-connected nodes. IC Role: The SoC runs application firmware and controls peripherals including SPI, I2C, I2S, UART, RMT, LED PWM, ADC, temperature sensor, timers, USB serial/JTAG on supported variants, and GPIO matrix. Use Value: Combines local MCU control and wireless connectivity without a separate network processor. |
Use Scenario: High-volume connected products, custom certified modules, smart-home devices, industrial controllers, and appliance control boards. IC Role: SoC-level design reduces module dependency but requires full RF validation, production test, and certification planning. Use Value: Provides BOM and layout flexibility when engineering resources can support complete hardware validation. |
Equivalent & Alternatives
When evaluating a ESP32-C3FH4X equivalent, engineers should compare wireless protocol support, CPU architecture, memory configuration, antenna option, GPIO availability, package footprint, module certification route, software compatibility, and long-term availability.
| Alternative Part | Technical Difference | Application Difference | Selection Advice |
|---|---|---|---|
| ESP32-C3-MINI-1 / ESP32-C3-MINI-1U | Compact module options with integrated or external antenna variants. | Used where the RISC-V Wi-Fi/BLE device should be integrated as a certified module. | Choose ESP32-C3FH4X when the target BOM requires its exact flash and antenna suffix. |
| ESP8684 series | Cost-optimized ESP32-C2-group alternative with fewer GPIO resources. | Used for simple low-cost Wi-Fi/BLE endpoints. | Use ESP32-C3 when more GPIO or established ESP32-C3 ecosystem compatibility is needed. |
| ESP32-S3 family | Dual-core Wi-Fi/BLE family with vector instructions and more peripheral resources. | Used for AIoT, voice, HMI, and heavier application workloads. | Use ESP32-C3 for lower-cost, lower-power Wi-Fi/BLE control nodes. |
Selection Recommendation: ESP32-C3FH4X is most suitable when the design requirements align with the ESP32-C3 platform, the exact ordering suffix, and the Espressif datasheet or module reference design. Replacement should not be based on wireless protocol alone; memory size, antenna configuration, boot pins, RF layout, and software compatibility must also match.
Quality
For reliable deployment, ESP32-C3FH4X should be sourced as an original Espressif Systems component or Espressif development product with traceable procurement records, manufacturer labeling verification, ESD-safe handling, and moisture-sensitive-device control where applicable.
Inspection processes may include package marking review, reel or tray label verification, module shield inspection, solderability testing, X-ray inspection for modules or SiP devices, RF functional testing, programming verification, and incoming inspection under production requirements.
Because Espressif devices combine RF, MCU, memory, and security resources, production reliability depends on correct power sequencing, RF layout, boot-mode configuration, firmware validation, thermal margin, antenna matching, and ESP-IDF software compatibility.
Availability
ESP32-C3FH4X available at Aetrix Electronics and suitable for engineering evaluation, prototype development, production sourcing, IoT product manufacturing, module replacement, and wireless embedded system integration.
Supply support may include reel or tray procurement, module sourcing, development-board sourcing, scheduled delivery planning, BOM continuity assistance, shortage mitigation, and long-term lifecycle support for connected-device production.
For production deployment, confirming the exact part number, datasheet revision, memory suffix, antenna type, operating temperature, package footprint, programming method, and software compatibility helps reduce sourcing and design-in risk.
Manufacturer
Espressif Systems is a semiconductor company focused on wireless SoCs, modules, development platforms, and software ecosystems for IoT, AIoT, smart home, industrial control, consumer electronics, low-power sensing, and connected embedded devices.
The Espressif portfolio includes ESP32, ESP32-S, ESP32-C, ESP32-H, ESP868x, ESP8266, modules, DevKits, production tools, and software frameworks such as ESP-IDF, enabling designers to build Wi-Fi, Bluetooth, Thread, Zigbee, Matter, and multi-protocol connected products.
FAQ
What is ESP32-C3FH4X used for?
ESP32-C3FH4X is used for ESP32-C3 Custom SoC Designs, RF and Antenna Controlled Layouts, Embedded Control and Connectivity, Cost-Optimized Production Hardware. It is selected when the final PCB needs direct SoC-level integration, custom RF layout, custom power design, and full control of peripheral routing on the ESP32-C3 platform.
What platform or product type does ESP32-C3FH4X belong to?
ESP32-C3FH4X is an ESP32-C3-based wireless MCU SoC. Wireless MCU SoC from the ESP32-C3 platform. single-core 32-bit RISC-V processor up to 160 MHz.
What hardware design points matter for ESP32-C3FH4X?
For ESP32-C3FH4X, PCB design should verify RF matching and antenna layout, crystal or clock circuit, flash or PSRAM connection if external, power-rail decoupling, boot strapping, programming path, and GPIO matrix assignment.
What configuration details should be checked for ESP32-C3FH4X?
For ESP32-C3FH4X, the main configuration points are CPU Architecture: single-core 32-bit RISC-V processor up to 160 MHz. Wireless Connectivity: 2.4 GHz Wi-Fi 4 and Bluetooth 5 Low Energy. Peripheral Resources: SPI, I2C, I2S, UART, RMT, LED PWM, ADC, temperature sensor, timers, USB serial/JTAG on supported variants, and GPIO matrix.
What are common ESP32-C3FH4X alternative or comparison points?
ESP32-C3FH4X should be compared with related ESP32-C3 SoCs by CPU architecture, wireless protocol support, peripheral set, embedded memory option, package, security resources, and software compatibility.
What documents are important for ESP32-C3FH4X design or production?
For ESP32-C3FH4X, use the chip datasheet, hardware design guidelines, technical reference manual, package drawing, RF design notes, and software development documentation before schematic and PCB release.
ESP32-C3FH4X Specifications
- Product attributes
- Attribute value
- Manufacturer:
- Espressif Systems
- Series:
- ESP32-C3
- Package/Case:
- 32-VFQFN Exposed Pad
- Packaging:
- Tape & Reel (TR)
- Product Status:
- Active
- Programmable:
- -
- Type:
- TxRx + MCU
- RF Family/Standard:
- Bluetooth, WiFi
- Protocol:
- 802.11b/g/n, Bluetooth v5.0
- Modulation:
- -
- Frequency:
- -
- Data Rate (Max):
- 150Mbps
- Power - Output:
- 20dBm
- Sensitivity:
- -97dBm
- Memory Size:
- 384kB ROM, 408kB SRAM
- Serial Interfaces:
- ADC, GPIO, I2C, I2S, PWM, SDIO, SPI, TWAI, UART
- GPIO:
- 22
- Voltage - Supply:
- 2.3V ~ 3.6V
- Current - Receiving:
- 84mA ~ 87mA
- Current - Transmitting:
- 276mA ~ 335mA
- Operating Temperature:
- -40°C ~ 105°C (TA)
- Grade:
- -
- Qualification:
- -
- Supplier Device Package:
- 32-QFN (5x5)
ESP32-C3FH4X FAQ
1.How can I place an order for ESP32-C3FH4X through Aetrix?
Please submit a Request for Quotation (RFQ) for ESP32-C3FH4X 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 ESP32-C3FH4X reliable?
The price and inventory of ESP32-C3FH4X are updated periodically and may fluctuate due to market conditions. Stock and pricing data are typically refreshed every 24 hours. Quotation validity for ESP32-C3FH4X is usually 5 days.
3.What payment methods are accepted for ESP32-C3FH4X?
We accept Wire Transfer, PayPal, Credit Card, Western Union, MoneyGram, and Escrow for ESP32-C3FH4X transactions.
Note: Certain payment methods may incur a processing fee.
4.How is shipping managed for ESP32-C3FH4X?
ESP32-C3FH4X orders can be shipped via leading logistics carriers, including DHL, UPS, FedEx, TNT, or Registered Mail.
Once your ESP32-C3FH4X 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 ESP32-C3FH4X?
For technical support, including ESP32-C3FH4X datasheets, pinout diagrams, or application guidance, please contact our engineering support team. They can provide detailed documentation and assistance for your ESP32-C3FH4X requirements.
6.How does Aetrix verify that ESP32-C3FH4X is sourced from the original manufacturer or authorized distributors?
All ESP32-C3FH4X 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 ESP32-C3FH4X meets industry standards.
7.What is the process for return or replacement of ESP32-C3FH4X?
All ESP32-C3FH4X units undergo pre-shipment inspection (PSI). If there is an issue with ESP32-C3FH4X, 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 ESP32-C3FH4X part is unused and in its original packaging.
Return procedure for ESP32-C3FH4X:
1.Submit a request within 90 days.
2.Obtain a Return Material Authorization (RMA) from Aetrix.
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