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RF Transceiver ICs

Image Part Number Description / PDF Quantity Rfq
CC1000-RTB1

CC1000-RTB1

Texas Instruments

RF AND BASEBAND CIRCUIT, CMOS, P

50
MKW41Z512VHT4R

MKW41Z512VHT4R

NXP Semiconductors

IC RF TXRX+MCU 802.15.4 48VFLGA

0
EFR32FG1P132F256GM32-C0

EFR32FG1P132F256GM32-C0

Silicon Labs

IC RF TXRX+MCU 32VFQFN

725
SI4461-C2A-GM

SI4461-C2A-GM

Silicon Labs

IC RF TXRX+MCU ISM<1GHZ 20VFQFN

0
EFR32FG1P131F256GM48-C0R

EFR32FG1P131F256GM48-C0R

Silicon Labs

IC RF TXRX+MCU 802.15.4 48VFQFN

0
EFR32FG14P233F256GM48-B

EFR32FG14P233F256GM48-B

Silicon Labs

IC RF TXRX+MCU 802.15.4 48VFQFN

102
NCK2912AHN/T0BY

NCK2912AHN/T0BY

NXP Semiconductors

IC RF TXRX+MCU 48HVQFN

0
CYBL10563-68FLXIT

CYBL10563-68FLXIT

Cypress Semiconductor

IC RF TXRX+MCU BLUETOOTH 68XFBGA

7516
EFR32FG13P232F512GM48-C

EFR32FG13P232F512GM48-C

Silicon Labs

IC RF 802.15.4 48VFQFN

309
ATMEGA1281R212-MU

ATMEGA1281R212-MU

Roving Networks / Microchip Technology

IC RF TXRX+MCU 802.15.4 64TQFP

135
ATSAMR35J16BT-I/7JX

ATSAMR35J16BT-I/7JX

Roving Networks / Microchip Technology

IC RF TXRX+MCU 802.15.4 64TFBGA

2995
EFR32MG12P232F512GM68-C

EFR32MG12P232F512GM68-C

Silicon Labs

IC RF TXRX+MCU 802.15.4 68VFQFN

0
ATSAMR35J18BT-I/7JX

ATSAMR35J18BT-I/7JX

Roving Networks / Microchip Technology

IC RF TXRX+MCU 802.15.4 64TFBGA

2963
EFR32MG12P431F1024GM68-CR

EFR32MG12P431F1024GM68-CR

Silicon Labs

IC RF TXRX+MCU 802.15.4 68VFQFN

0
CC2650F128RHBR

CC2650F128RHBR

Texas Instruments

IC RF TXRX+MCU 802.15.4 32VFQFN

0
SI1061-A-GM

SI1061-A-GM

Silicon Labs

IC RF TXRX+MCU ISM<1GHZ 36-WFQFN

0
SI1021-B-GM3

SI1021-B-GM3

Silicon Labs

IC RF TXRX+MCU ISM<1GHZ 85VFLGA

0
NCK2913AHN/T2CY

NCK2913AHN/T2CY

NXP Semiconductors

IC RECEIVER 3CH 48HVQFN

0
ADF7021-NBCPZ-RL7

ADF7021-NBCPZ-RL7

Analog Devices, Inc.

IC RF TXRX ISM<1GHZ 48VFQFN

452
DW1000-I-TR13

DW1000-I-TR13

IC RF TXRX 802.15.4 48QFN

37550

RF Transceiver ICs

1. Overview

RF (Radio Frequency) and IF (Intermediate Frequency) transceiver ICs are integrated circuits that enable wireless communication by transmitting and receiving radio signals. These devices are critical in modern technologies, supporting applications from cellular networks to IoT (Internet of Things). RFID (Radio-Frequency Identification) RF transceivers specialize in short-range communication for identification and tracking systems. Their miniaturization, energy efficiency, and reliability have driven advancements in connectivity across industries.

2. Major Types and Functional Classification

Type Functional Features Application Examples
Low-Power RF Transceivers Optimized for energy efficiency, supports sub-1GHz and 2.4GHz bands IoT sensors, smart meters, wearable devices
High-Performance RF Transceivers High output power (up to +20dBm), low phase noise 5G base stations, military communication systems
Multi-Band RF Transceivers Supports multiple frequency bands (e.g., 400MHz-6GHz) Dual-mode radios, global navigation systems
Integrated RFID Transceivers Embedded protocol handling, on-chip modulation/demodulation Inventory tracking, access control systems

3. Structure and Components

Typical RF transceiver ICs include:

  • Transmitter Section: Power Amplifier (PA), up-conversion mixer, frequency synthesizer
  • Receiver Section: Low-Noise Amplifier (LNA), down-conversion mixer, channel filter
  • Digital Baseband: ADC/DAC, error correction, protocol engine
  • Process Technology: CMOS, SiGe, or GaAs for high-frequency performance
  • Package Types: QFN (Quad Flat No-leads), BGA (Ball Grid Array)

4. Key Technical Specifications

Parameter Description Importance
Frequency Range Operational bandwidth (e.g., 868MHz-915MHz, 2.4GHz-5.8GHz) Determines application compatibility
Output Power Transmit power level (e.g., -20dBm to +20dBm) Impacts transmission distance and regulatory compliance
Receiver Sensitivity Minimum detectable signal level (e.g., -120dBm) Defines signal quality in noisy environments
Data Rate Maximum throughput (e.g., 1Mbps-1Gbps) Affects real-time data transmission capability
Power Consumption Operating current/voltage requirements Crucial for battery-powered devices

5. Application Areas

  • Telecommunications: 5G small cells, Wi-Fi 6 access points
  • Industrial IoT: Predictive maintenance sensors
  • Automotive: Tire Pressure Monitoring Systems (TPMS), keyless entry
  • Healthcare: Remote patient monitoring devices
  • Retail: Smart shelves with RFID inventory tracking

6. Leading Manufacturers and Products

Manufacturer Representative Product Key Features
TI (Texas Instruments) CC1352P Sub-1GHz & 2.4GHz dual-band, +7dBm output power
Nordic Semiconductor nRF52840 Bluetooth 5.2, 2.4GHz, 128-bit AES encryption
STMicroelectronics S2-LP Very low-power (14mA RX), sub-GHz transceiver
Infineon Technologies BTS720 Automotive-grade RFID transceiver for immobilizers

7. Selection Guidelines

Key considerations include:

  • Frequency band alignment with regulatory standards (FCC, ETSI)
  • Power budget vs. transmission range requirements
  • Integration level (e.g., on-chip MCU, external PA needs)
  • Environmental factors (temperature range, EMI resilience)
  • Cost vs. performance trade-offs for mass production

8. Industry Trends

Future developments include:

  • Ultra-low-power designs for energy-harvesting IoT nodes
  • Massive MIMO integration for 6G infrastructure
  • AI-enhanced spectrum management algorithms
  • Expanded use of mmWave bands (24GHz+) for high-speed applications
  • Standardization of RFID protocols for global supply chains
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