PL1167中文资料-2.4GHz无线射频收发芯片资料

LL217-TX模组集成 2.4G无线收发及低功耗无线收发及低功耗 8bit MCU微处理器，工作在微处理器，工作在 2400MHz-2483.5MHz全球通用全球通用 ISM频段。

最大发射功率频段。

最大发射功率频段。

最大发射功率 2dBm，接收灵敏度，接收灵敏度 -92dBm。

LL217-TX内嵌无线跳频内嵌无线跳频抗干扰收发传输协议收发传输协议，无需进行二次开发，使用简无需进行二次开发，使用简无需进行二次开发，使用简单快捷。

LL217-TX 支持独立 8通道的开关量传输。

应用范围：
⚫无线遥控器
⚫遥控玩具
⚫安防系统
⚫有源 RFID
⚫ LED灯
主要参数：
⚫供电压： 2.2V~3.6V
⚫最大发射功率： 2dBm
⚫遥控器工作电流：5mA
⚫休眠电流：小于 5uA
⚫调制方式： GFSK
⚫空中速率： 250kbps
⚫接收灵敏度： -92dBm（0.1%BER）
⚫传输距离： 50m（开阔地）
⚫响应时间：小于 25ms
⚫封装： SOP16。

Rev. 1.2012021-10-13BC5602RF 2.4GHz收发器特性•频率带宽：2402~2480MHz •支持3线或4线SPI 接口 •输入电压范围宽：1.9V~3.6V•可编程数据速率：125/250/500Kbps•可编程TX 输出功率：5dBm (最大 +6dBm ) •低电流消耗♦Deep Sleep 模式电流0.5μA ，支持数据保存♦TX 电流：25mA @ 5dBm ♦RX 电流：17mA @ 250Kbps •两个Sleep 模式♦Middle Sleep 模式，支持快速XO 启动 ♦常规的Light Sleep 模式 •RX 灵敏度♦-97dBm @ 250Kbps 无线数据速率 •片上VCO 以及带内置回路滤波器的小数N 分频合成器•支持16MHz 晶振(±20ppm) •数据包处理 ♦数据白化♦自动应答/重发 ♦CRC 可选协议 ♦支持Burst 数据包 ♦支持自动ACK 处理♦适用于1:6星型网络的6个数据管道 •符合FCC/ETSI•封装类型：16-pin QFN (3mm ×3mm)概述BC5602为高性能、低成本的完全集成的CMOS RF GFSK 收发器，可用于2.4GHz 频 段的无线应用。

该芯片内置一个高集成的2.4GHz 收发器和一个基带调制解调器，可编程数据速率为125Kbps 、250Kbps 和500 Kbps 。

数据处理特性包括3层32字节TX/RX FIFO 和数据包处理，如白化和CRC 校验。

BC5602支持Middle Sleep 模式，仅消耗30μA 微量电流即可实现XO 快速启动。

该芯片可在2.4GHz 频段数据速率为250Kbps 时实现-97dBm 的灵敏度，提供+5dBm TX 输出功率时的电流消耗为25mA 。

完全内置的小数N 分频合成器所支持的频率范围宽，分辨率高。

外部主控MCU 可通过一个3线或4线的SPI 接口访问BC5602。

EFR32MG12 2.4 GHz 19 dBm Radio Board BRD4161A Reference ManualRADIO BOARD FEATURES•Wireless SoC:EFR32MG12P432F1024GL125•CPU core: ARM Cortex ®-M4 with FPU •Flash memory: 1024 kB •RAM: 256 kB•Operation frequency: 2.4 GHz •Transmit power: 19 dBm•Integrated PCB antenna, UFL connector (optional).•Touch Slider•Crystals for LFXO and HFXO: 32.768 kHz and 38.4 MHz.The BRD4161A Mighty Gecko Radio Board enables developers to develop Zigbee ®, Thread,Bluetooth ® low energy and proprietary wireless applications. The board con-tains a Mighty Gecko Wireless System on Chip 2.4 GHz and optimized for operation with 19 dBm output power. With the on-board printed antenna and RF connector radi-ated and conducted testing is supported.The BRD4161A Mighty Gecko Radio Board plugs into the Wireless Starter Kit Main-board provided with the Mighty Gecko Starter Kit to get access to display, buttons and additional features from Expansion Boards. With the supporting Simplicity Studio suite of tools, developers can take advantage of graphical wireless application development; mesh networking debug and packet trace; and visual energy profiling and optimization. The board also serves as an RF reference design for applications targeting 2.4 GHz wireless operation with 19 dBm output power.This document contains brief introduction and description of the BRD4161A Radio Board features focusing on the RF sections and performance.| Smart. Connected. Energy-friendly.Rev. 1.00Introduction 1. IntroductionThe EFR32 Mighty Gecko Radio Boards provide a development platform (together with the Wireless Starter Kit Mainboard) for the Silicon Labs EFR32 Mighty Gecko Wireless System on Chips and serve as reference designs for the matching network of the RF inter-face.The BRD4161A Radio Board is designed to operate in the 2400-2483.5 MHz band with the RF matching network optimized to operate with 19 dBm output power.To develop and/or evaluate the EFR32 Mighty Gecko, the BRD4161A Radio Board can be connected to the Wireless Starter Kit Main-board to get access to display, buttons and additional features from Expansion Boards and also to evaluate the performance of the RF interface.2. Radio Board Connector2.1 IntroductionThe board-to-board connector scheme allows access to all EFR32MG12 GPIO pins as well as the RESETn signal. For more informa-tion on the functions of the available pin functions, see the EFR32MG12 data sheet.2.2 Radio Board Connector Pin AssociationsThe figure below shows the pin mapping on the connector to the radio pins and their function on the Wireless Starter Kit Mainboard.GNDF9 / PA3 / VCOM_RTS 3v3VCOM_RTS / PA3 / P36P200Upper RowNC / P38NC / P40PF9 / P42PF11 / P44DEBUG.TMS_SWDIO / PF1 / F0DISP_ENABLE / PD15 / F14UIF_BUTTON0 / PF6 / F12UIF_LED1 / PF4 / F10VCOM_CTS / PA2 / F8DEBUG.RESET / RADIO_#RESET / F4DEBUG.TDO_SWO / PF2 / F2DISP_SI / PC6 / F16VCOM_TXD / PA0 / F6PTI_DATA / PB12 / F20DISP_EXTCOMIN / PD13 / F18USB_VBUS5VBoard ID SCLGNDBoard ID SDAUSB_VREG F7 / PA1 / VCOM_RXD F5 / PA5 / VCOM_ENABLE F3 / PF3 / DEBUG.TDIF1 / PF0 / DEBUG.TCK_SWCLK P45 / PF12P43 / PF10P41 / PF8P39 / NC P37/ PB10 / SENSOR_ENABLE F11 / PF5 / UIF_LED1F13 / PF7 / UIF_BUTTON1F15 / PC8 / DISP_SCLK F17 / PD14 / DISP_SCS F19 / PB13 / PTI_FRAME F21 / PB11 / PTI_CLK GND VMCU_IN PD8 / P0P201Lower RowPD9 / P2PD10 / P4PD11 / P6GNDNCP35 / PA2 / VCOM_CTS P7 / PA9P5 / PA8P3 / PA7P1 / PA6P33 / PA0 / VCOM_TXD P31 / PK2P29 / PK0P27 / PJ14P25 / PI2P23 / PI0P21 / PF14P19 / NC P17 / PC5P15 / PB9P13 / PC11P11 / PB7P9 / PB6VCOM_RXD / P34 / P34BODEN / P32PK1/ P30PJ15 / P28PI3 / P26PI1 / P24PF15 / P22PF13 / P20NC / P18PC4 / P16PB8 / P14PC10 / P12PC9 / P10PD12 / P8Figure 2.1. BRD4161A Radio Board Connector Pin MappingRadio Board Connector3. Radio Board Block Summary3.1 IntroductionThis section gives a short introduction to the blocks of the BRD4161A Radio Board.3.2 Radio Board Block DiagramThe block diagram of the EFR32MG Radio Board is shown in the figure below.Figure 3.1. BRD4161A Block Diagram3.3 Radio Board Block Description3.3.1 Wireless MCUThe BRD4161A Mighty Gecko Radio Board incorporates an EFR32MG12P432F1024GL125 Wireless System on Chip featuring 32-bit Cortex®-M4 with FPU core, 1024 kB of flash memory and 256 kB of RAM and a 2.4 GHz band transceiver with output power up to 19 dBm. For additional information on the EFR32MG12P432F1024GL125, refer to the EFR32MG12 Data Sheet.3.3.2 LF Crystal Oscillator (LFXO)The BRD4161A Radio Board has a 32.768 kHz crystal mounted.3.3.3 HF Crystal Oscillator (HFXO)The BRD4161A Radio Board has a 38.4 MHz crystal mounted.| Smart. Connected. Energy-friendly.Rev. 1.00 | 33.3.4 Matching Network for 2.4 GHzThe BRD4161A Radio Board incorporates a 2.4 GHz matching network which connects the 2.4 GHz TRX pin of the EFR32MG12 to the one on-board printed Inverted-F antenna. The component values were optimized for the 2.4 GHz band RF performace and current con-sumption with 19 dBm output power.For detailed description of the matching network, see Chapter 4.2.1 Description of the 2.4 GHz RF Matching.3.3.5 Inverted-F AntennaThe BRD4161A Radio Board includes a printed Inverted-F antenna (IFA) tuned to have close to 50 Ohm impedance at the 2.4 GHz band.For detailed description of the antenna see Chapter 4.5 Inverted-F Antenna.3.3.6 UFL ConnectorTo be able to perform conducted measurements, Silicon Labs added an UFL connector to the Radio Board. The connector allows an external 50 Ohm cable or antenna to be connected during design verification or testing.Note: By default the output of the matching network is connected to the printed Inverted-F antenna by a series component. It can be connected to the UFL connector as well through a series 0 Ohm resistor which is not mounted by default. For conducted measurements through the UFL connector the series component to the antenna should be removed and the 0 Ohm resistor should be mounted (see Chapter 4.2 Schematic of the RF Matching Network for further details).3.3.7 Radio Board ConnectorsTwo dual-row, 0.05” pitch polarized connectors make up the EFR32MG Radio Board interface to the Wireless Starter Kit Mainboard. For more information on the pin mapping between the EFR32MG12P432F1024GL125 and the Radio Board Connector, refer to Chapter 2.2 Radio Board Connector Pin Associations.3.3.8 Capacitive Touch SliderThe touch slider (T2) utilizes the capacitive touch capability of the Capacitance Sense Module of the EFR32MG12. The slider interpo-lates 4 separate pads to find the exact position of a finger.The figure below shows the pin mapping of the touch slider to the Wireless SoC.Wireless SoCFigure 3.2. Touch Slider Pin MappingRev. 1.00 | 44. RF Section4.1 IntroductionThis section gives a short introduction to the RF section of the BRD4161A.4.2 Schematic of the RF Matching NetworkThe schematic of the RF section of the BRD4161A Radio Board is shown in the following figure.2.4 GHz Matching 2.4 GHz RF OutputSelection & Inverted-F AntennaFigure 4.1. Schematic of the RF Section of the BRD4161A4.2.1 Description of the 2.4 GHz RF MatchingThe 2.4 GHz matching connects the 2G4RF_IOP pin to the on-board printed Inverted-F Antenna. The 2G4RF_ION pin is connected to ground. For higher output powers (13 dBm and above), besides the impedance matching circuitry, it is recommended to use additional harmonic filtering as well at the RF output. The targeted output power of the BRD4161A board is 19 dBm. Therefore, the RF output of the IC is connected to the antenna through a four-element impedance matching and harmonic filter circuitry.For conducted measurements the output of the matching network can also be connected to the UFL connector by removing the series R1 component between the antenna and the output of the matching and adding a 0 Ohm resistor to the R2 resistor position between the output of the matching and the UFL connector.4.3 RF Section Power SupplyOn the BRD4161A Radio Board the power supply pins of the RF section (RFVDD, PAVDD) are directly connected to the output of the on-chip DC-DC converter. This way, by default, the DC-DC converter provides 1.8 V for the entire RF section (for details, see the sche-matic of the BRD4161A).4.4 Bill of Materials for the 2.4 GHz MatchingThe Bill of Materials of the 2.4 GHz matching network of the BRD4161A Radio Board is shown in the following table.| Smart. Connected. Energy-friendly.Rev. 1.00 | 5Table 4.1. Bill of Materials for the BRD4161A 2.4GHz RF Matching Network4.5 Inverted-F AntennaThe BRD4161A Radio Board includes an on-board printed Inverted-F Antenna tuned for the 2.4 GHz band. Due to the design restric-tions of the Radio Board, the input of the antenna and the output of the matching network can't be placed directly next to each other. As a result, a 50 Ohm transmission line was necessary to connect them. With the actual line length the impedance of the antenna at the double-harmonic frequency is transformed closer to a "critical load impedance range" resulting in the radiated level of the harmonic increases.To reduce the harmonic radiation a tuning component was used between the matching network output and the antenna input. For the actual Radio Board design (with the actual transmission line length) a small value inductor was used (instead of the R1 resistor with value of 1.8 nH) to transform the impedance at the double-frequency harmonic away from the critical region while keeping the impe-dance at the funamental close to 50 Ohm. With this the suppression of the radiated double-frequency harmonic increases by approxi-mately 3-4 dB. The resulting impedance and reflection measured at the output of the matcing network are shown in the following figure. As it can be observed the impedance is close to 50 Ohm (the reflection is better than -10 dB) for the entire 2.4 GHz band.Figure 4.2. Impedance and Reflection of the Inverted-F Antenna of the BRD4161A Board Measured from the Matching Output Note: The same value and type of 1.8 nH inductor was used as the one in the matching network (L1). | Smart. Connected. Energy-friendly.Rev. 1.00 | 65. Mechanical DetailsThe BRD4161A Mighty Gecko Radio Board is illustrated in the figures below.Figure 5.1. BRD4161A Top View24 mmConnectorConnector Figure 5.2. BRD4161A Bottom ViewMechanical DetailsRev. 1.00 | 7EMC Compliance 6. EMC Compliance6.1 IntroductionCompliance of the fundamental and harmonic levels is tested against the following standards:• 2.4 GHz:•ETSI EN 300-328•FCC 15.2476.2 EMC Regulations for 2.4 GHz6.2.1 ETSI EN 300-328 Emission Limits for the 2400-2483.5 MHz BandBased on ETSI EN 300-328 the allowed maximum fundamental power for the 2400-2483.5 MHz band is 20 dBm EIRP. For the unwan-ted emissions in the 1 GHz to 12.75 GHz domain the specified limit is -30 dBm EIRP.6.2.2 FCC15.247 Emission Limits for the 2400-2483.5 MHz BandFCC 15.247 allows conducted output power up to 1 Watt (30 dBm) in the 2400-2483.5 MHz band. For spurious emmissions the limit is -20 dBc based on either conducted or radiated measurement, if the emission is not in a restricted band. The restricted bands are speci-fied in FCC 15.205. In these bands the spurious emission levels must meet the levels set out in FCC 15.209. In the range from 960 MHz to the frequency of the 5th harmonic it is defined as 0.5 mV/m at 3 m distance (equals to -41.2 dBm in EIRP).Additionally, for spurious frequencies above 1 GHz, FCC 15.35 allows duty-cycle relaxation to the regulatory limits. For the EmberZNet PRO the relaxation is 3.6 dB. Therefore, the -41.2 dBm limit can be modified to -37.6 dBm.If operating in the 2400-2483.5 MHz band the 2nd, 3rd and 5th harmonics can fall into restricted bands. As a result, for those the -37.6 dBm limit should be applied. For the 4th harmonic the -20 dBc limit should be applied.6.2.3 Applied Emission Limits for the 2.4 GHz BandThe above ETSI limits are applied both for conducted and radiated measurements.The FCC restricted band limits are radiated limits only. Besides that, Silicon Labs applies those to the conducted spectrum i.e., it is assumed that, in case of a custom board, an antenna is used which has 0 dB gain at the fundamental and the harmonic frequencies. In that theoretical case, based on the conducted measurement, the compliance with the radiated limits can be estimated.The overall applied limits are shown in the table below.Table 6.1. Applied Limits for Spurious Emissions for the 2.4 GHz Band | Smart. Connected. Energy-friendly.Rev. 1.00 | 87. RF Performance7.1 Conducted Power MeasurementsDuring measurements, the EFR32MG Radio Board was attached to a Wireless Starter Kit Mainboard which was supplied by USB. The voltage supply for the Radio Board was 3.3 V.7.1.1 Conducted Measurements in the 2.4 GHz bandThe BRD4161A board was connected directly to a Spectrum Analyzer through its UFL connector (the R1 component was removed and a 0 Ohm resistor was soldered to the R2 resistor position). During measurements, the voltage supply for the board was 3.3 V provided by the mainboard. The supply for the radio (RFVDD) was 1.8 V provided by the on-chip DC-DC converter, the supply for the power amplifier (PAVDD) was 3.3 V (for details, see the schematic of the BRD4161A). The transceiver was operated in continuous carrier transmission mode. The output power of the radio was set to 19 dBm.The typical output spectrum is shown in the following figure.Figure 7.1. Typical Output Spectrum of the BRD4161AAs it can be observed, the fundamental is slightly lower than 19 dBm limit and the strongest unwanted emission is the double-frequency harmonic and it is under the -37.6 dBm applied limit.Note: The conducted measurement is performed by connecting the on-board UFL connector to a Spectrum Analyzer through an SMA Conversion Adapter (P/N: HRMJ-U.FLP(40)). This connection itself introduces approximately 0.3 dB insertion loss.RF PerformanceRev. 1.00 | 97.2 Radiated Power MeasurementsDuring measurements, the EFR32MG Radio Board was attached to a Wireless Starter Kit Mainboard which was supplied by USB. The voltage supply for the Radio Board was 3.3 V. The radiated power was measured in an antenna chamber by rotating the DUT 360degrees with horizontal and vertical reference antenna polarizations in the XY , XZ and YZ cuts. The measurement axes are shown inthe figure below.Figure 7.2. DUT: Radio Board with the Wireless Starter Kit Mainboard (Illustration)Note: The radiated measurement results presented in this document were recorded in an unlicensed antenna chamber. Also the radi-ated power levels may change depending on the actual application (PCB size, used antenna, and so on). Therefore, the absolute levels and margins of the final application are recommended to be verified in a licensed EMC testhouse.7.2.1 Radiated Measurements in the 2.4 GHz bandFor the transmitter antenna the on-board printed Inverted-F antenna of the BRD4161A board was used (the R1 component was moun-ted). During measurements, the board was attached to a Wireless Starter Kit Mainboard (BRD4001 (Rev. A02) ) which was supplied through USB. During the measurements the voltage supply for the board was 3.3 V provided by the mainboard. The supply for the radio (RFVDD) was 1.8 V provided by the on-chip DC-DC converter, the supply for the power amplifier (PAVDD) was 3.3 V (for details, see the schematic of the BRD4161A). The transceiver was operated in continuous carrier transmission mode. The output power of the radio was set to 19 dBm based on the conducted measurement.The results are shown in the table below.Table 7.1. Maximums of the measured radiated powers in EIRP [dBm]As it can be observed, thanks to the high gain of the Inverted-F antenna, the level of the fundamental is higher than 19 dBm. The stron-gest harmonic is the double-frequency one and thanks to the additional suppression provided by the instead of the R1 resistor its level is under -50 dBm.RF PerformanceEMC Compliance Recommendations 8. EMC Compliance Recommendations8.1 Recommendations for 2.4 GHz ETSI EN 300-328 complianceAs it was shown in the previous chapter, the radiated power of the fundamental of the BRD4161A Mighty Gecko Radio Board complies with the 20 dBm limit of the ETSI EN 300-328 in case of the conducted measurement but due to the high antenna gain the radiated power is higher than the limit by 2 dB. In order to comply, the output power should be reduced (with different antennas, depending on the gain of the used antenna, the necessary reduction can be different). The harmonic emissions are under the -30 dBm limit. Although the BRD4161A Radio Board has an option for mounting a shielding can, that is not required for the compliance.8.2 Recommendations for 2.4 GHz FCC 15.247 complianceAs it was shown in the previous chapter, the radiated power of the fundamental of the BRD4161A Mighty Gecko Radio Board complies with the 30 dBm limit of the FCC 15.247. The harmonic emissions are under the -37.6 dBm applied limit both in case of the conducted and the radiated measurements. Although the BRD4161A Radio Board has an option for mounting a shielding can, that is not required for the compliance.Document Revision History 9. Document Revision HistoryTable 9.1. Document Revision HistoryBoard Revision History 10. Board Revision HistoryTable 10.1. BRD4161A Radio Board RevisionsErrata 11. ErrataThere are no known errata at present.Table of Contents1. Introduction (1)2. Radio Board Connector (2)2.1 Introduction (2)2.2 Radio Board Connector Pin Associations (2)3. Radio Board Block Summary (3)3.1 Introduction (3)3.2 Radio Board Block Diagram (3)3.3 Radio Board Block Description (3)3.3.1 Wireless MCU (3)3.3.2 LF Crystal Oscillator (LFXO) (3)3.3.3 HF Crystal Oscillator (HFXO) (3)3.3.4 Matching Network for 2.4 GHz (4)3.3.5 Inverted-F Antenna (4)3.3.6 UFL Connector (4)3.3.7 Radio Board Connectors (4)3.3.8 Capacitive Touch Slider (4)4. RF Section (5)4.1 Introduction (5)4.2 Schematic of the RF Matching Network (5)4.2.1 Description of the 2.4 GHz RF Matching (5)4.3 RF Section Power Supply (5)4.4 Bill of Materials for the 2.4 GHz Matching (5)4.5 Inverted-F Antenna (6)5. Mechanical Details (7)6. EMC Compliance (8)6.1 Introduction (8)6.2 EMC Regulations for 2.4 GHz (8)6.2.1 ETSI EN 300-328 Emission Limits for the 2400-2483.5 MHz Band (8)6.2.2 FCC15.247 Emission Limits for the 2400-2483.5 MHz Band (8)6.2.3 Applied Emission Limits for the 2.4 GHz Band (8)7. RF Performance (9)7.1 Conducted Power Measurements (9)7.1.1 Conducted Measurements in the 2.4 GHz band (9)7.2 Radiated Power Measurements (10)7.2.1 Radiated Measurements in the 2.4 GHz band (10)8. EMC Compliance Recommendations (11)8.1 Recommendations for 2.4 GHz ETSI EN 300-328 compliance (11)8.2 Recommendations for 2.4 GHz FCC 15.247 compliance (11)9. Document Revision History (12)10. Board Revision History (13)11. Errata (14)Table of Contents (15)Silicon Laboratories Inc.400 West Cesar Chavez Austin, TX 78701USASimplicity StudioOne-click access to MCU and wireless tools, documentation, software, source code libraries & more. Available for Windows, Mac and Linux!IoT Portfolio /IoTSW/HW/simplicityQuality/qualitySupport and CommunityDisclaimerSilicon Labs intends to provide customers with the latest, accurate, and in-depth documentation of all peripherals and modules available for system and software implementers using or intending to use the Silicon Labs products. Characterization data, available modules and peripherals, memory sizes and memory addresses refer to each specific device, and "Typical" parameters provided can and do vary in different applications. Application examples described herein are for illustrative purposes only. Silicon Labs reserves the right to make changes without further notice and limitation to product information, specifications, and descriptions herein, and does not give warranties as to the accuracy or completeness of the included information. Silicon Labs shall have no liability for the consequences of use of the information supplied herein. This document does not imply or express copyright licenses granted hereunder to design or fabricate any integrated circuits. The products are not designed or authorized to be used within any Life Support System without the specific written consent of Silicon Labs. A "Life Support System" is any product or system intended to support or sustain life and/or health, which, if it fails, can be reasonably expected to result in significant personal injury or death. Silicon Labs products are not designed or authorized for military applications. Silicon Labs products shall under no circumstances be used in weapons of mass destruction including (but not limited to) nuclear, biological or chemical weapons, or missiles capable of delivering such weapons.Trademark InformationSilicon Laboratories Inc.® , Silicon Laboratories®, Silicon Labs®, SiLabs® and the Silicon Labs logo®, Bluegiga®, Bluegiga Logo®, Clockbuilder®, CMEMS®, DSPLL®, EFM®, EFM32®, EFR, Ember®, Energy Micro, Energy Micro logo and combinations thereof, "the world’s most energy friendly microcontrollers", Ember®, EZLink®, EZRadio®, EZRadioPRO®, Gecko®, ISOmodem®, Precision32®, ProSLIC®, Simplicity Studio®, SiPHY®, Telegesis, the Telegesis Logo®, USBXpress® and others are trademarks or registered trademarks of Silicon Labs. ARM, CORTEX, Cortex-M3 and THUMB are trademarks or registered trademarks of ARM Holdings. Keil is a registered trademark of ARM Limited. All other products or brand names mentioned herein are trademarks of their respective holders.。

常用无线射频芯片目录CC1000PWR 超低功率射频收发器CC1010PAGR 射频收发器和微控制器CC1020RSSR 射频收发器CC1021RSSR 射频收发器CC1050PWR 超低功率射频发送器CC1070RSQR 射频发送器CC1100RTKR 多通道射频收发器CC1101RTKR 低于1GHz射频收发器CC1110F16RSPR 射频收发片上系统CC1110F32RSPR 射频收发片上系统CC1110F8RSPR 射频收发片上系统CC1111F16RSPR 射频收发片上系统CC1111F32RSPR 射频收发片上系统CC1111F8RSPR 射频收发片上系统CC1150RSTR 多通道射频发送器CC2400RSUR 多通道射频发送器CC2420RTCR 2.4GHz射频收发器CC2420ZRTCR 2.4GHz射频收发器CC2430F128RTCR ZigBee 芯片CC2430ZF128RTCR ZigBee 芯片CC2431RTCR 无线传感器网络芯片CC2431ZRTCR 无线传感器网络芯片CC2480A1RTCR 2.4GHzZigBee处理器CC2500RTKR 2.4GHz射频收发器CC2510F16RSPR 2.4GHz无线电收发器CC2510F32RSPR 2.4GHz无线电收发器CC2510F8RSPR 2.4GHz无线电收发器CC2511F16RSPR 2.4GHz无线电收发器CC2511F32RSPR 2.4GHz无线电收发器CC2511F8RSPR 2.4GHz无线电收发器CC2520RHDR 射频收发器CC2530F128RHAR 射频收发器CC2530F256RHAR 射频收发器CC2530F64RHAR 射频收发器CC2550RSTR 2.4GHz发送器CC2590RGVR 2.4GHz射频前端芯片CC2591RGVR 2.4GHz射频前端芯片CCZACC06A1RTCR 2.4GHZ ZigBee芯片TRF7900APWR 27MHz双路接收器TRF6900APT 射频收发器TRF6901PTG4 射频收发器TRF6901PTRG4 射频收发器TRF6903PTG4 射频收发器TRF6903PTRG4 射频收发器ADF7020-1BCPZ-RL7 射频收发IC ADF7020BCPZ-RL7 射频收发ICADF7021BCPZ-RL7 ISM无线收发IC ADF7021-NBCPZ-RL7 ISM无线收发IC ADF7025BCPZ-RL7 射频收发ICADF7010BRUZ-REEL7 ISM无线发射IC ADF7011BRUZ-RL7 ISM无线发射IC ADF7012BRUZ-RL7 UHF无线发射IC ADF7901BRUZ-RL7 ISM无线发射IC A7121A71C21AQF 2.4GHz射频收发器A7122A71C22AQF 2.4GHz射频收发器A7102A71C02AQF 射频收发ICA7103A71C03AUF 射频收发ICA7201A72C01AUF 射频接收ICA7202A72C02AUF 射频接收ICA7302A73C02AMF 射频发射ICA7105A71X05AQF 2.4GHz射频收发IC A7125A71X25AQF 2.4GHz射频收发IC A7325A73X25AQF 2.4GHz射频发射IC A7303AA73C03AQF FM发射芯片A7303AA73C03AUF FM发射芯片A7303BA73C03BUF FM发射芯片A7303BA73C03BQF FM发射芯片A7282A72N82AQF GPS接收芯片A7531BA75C31BQF GPS开关芯片A7532A75C32AQF GPS开关芯片A7533A75X33AQF GPS开关芯片A7533A75X33BQF GPS开关芯片AS3931 低功耗无线接收芯片AS3932BTSW 低功耗无线接收芯片AS3932BQFW 低功耗无线接收芯片AS3977BQFT FSK发射芯片AT86RF211DAI-R 射频收发ICAT86RF211SAHW-R 射频收发ICAT86RF212-ZU 射频收发ICAT86RF230-ZU 射频收发ICAT86RF231-ZU 射频收发ICATA2745M-TCQY 射频发送ICATA5428-PLQW 宽带收发ICATR2406-PNQG 2.4GHz射频收发IC T5750-6AQ 无线发射ICT5753-6AQ 无线发射ICT5754-6AQ 无线发射ICT7024-PGPM 前端收发器U2741B-NFB 无线发射ICAX5051 射频收发器ICAX5042 射频收发器ICAX5031 射频收发器ICAX50424 射频收发器ICAX6042 射频收发器ICCYRF6936-40LFXC 无线USB芯片CYRF7936-40LFXC 无线收发器芯片CYWUSB6932-28SEC 无线USB芯片CYWUSB6934-28SEC 无线USB芯片CYWUSB6934-48LFXC 无线USB芯片CYWUSB6935-28SEI 无线USB芯片CYWUSB6935-48LFI 无线USB芯片CYWUSB6935-48LFXC 无线USB芯片CYWUSB6935-48LFXI 无线USB芯片CYRF69103-40LFXC 无线射频芯片CYRF69213-40LFXC 无线射频芯片CYWUSB6953-48LFXC 无线USB芯片EM2420-RTR ZigBee 芯片EM260-RTR ZigBee 芯片EM250-RTR ZigBee 芯片EM351-RTR ZigBee 芯片EM357-RTR ZigBee 芯片PA5305 射频功率放大器PA2420 射频功率放大器PA2421 射频功率放大器PA2432 射频功率放大器FM2422 射频前端模块FM2422U 射频前端模块FM2427 射频前端模块FM2429 射频前端模块FM2429U 射频前端模块FM2446 射频前端模块FM7705 射频前端模块FM7707 射频前端模块MC13190FCR2 射频收发ICMC13191FCR2 射频收发ICMC13192FCR2 射频收发ICMC13193FCR2 射频收发ICMC13201FCR2 射频收发ICMC13202FCR2 射频收发ICMC13203FCR2 射频收发ICMC13211R2 射频收发ICMC13212R2 射频收发ICMC13213R2 射频收发ICMC13214R2 射频收发ICMC13224V 802.15.4/ZigBee芯片TDA5200 ASK接收器TDA5201 ASK接收器TDA5210 ASK/FSK接收器TDA5211 ASK/FSK接收器TDA5212 ASK/FSK接收器TDA5220 ASK/FSK接收器TDA5221 ASK/FSK接收器TDA7200 ASK/FSK接收器TDA7210 ASK/FSK接收器TDA5230 ASK/FSK接收器TDA5231 ASK/FSK接收器TDK5100 ASK/FSK发射器TDK5100F ASK/FSK发射器TDK5101 ASK/FSK发射器TDK5101F ASK/FSK发射器TDK5102 ASK/FSK发射器TDK5103A ASK发射器TDK5110 ASK/FSK发射器TDK5110F ASK/FSK发射器TDK5111 ASK/FSK发射器TDK5111F ASK/FSK发射器TDA7116F ASK/FSK发射器PMA7105 ASK/FSK发射器PMA7106 ASK/FSK发射器PMA7107 ASK/FSK发射器PMA7110 ASK/FSK发射器TDA5250 ASK/FSK收发器TDA5251 ASK/FSK收发器TDA5252 ASK/FSK收发器TDA5255 ASK/FSK收发器MAX1470EUI+T 无线接收IC MAX1471ATJ+T 无线接收IC MAX1472AKA+T 无线发射IC MAX1473EUI+T 无线接收IC MAX1479ATE+T 无线发射IC MAX7030HATJ+T 无线收发IC MAX7030LATJ+T 无线收发IC MAX7031LATJ+T 无线收发IC MAX7031MATJ50+T 无线收发ICMAX7032ATJ+T 无线收发IC MAX7033ETJ+T 无线接收IC MAX7044AKA+T 无线发射IC MAX7058ATG+T 无线发射IC MLX71121ELQ 射频接收IC MLX71122ELQ 射频接收IC TH71071EDC 射频接收IC TH71072EDC 射频接收IC TH7107EFC 射频接收IC TH71081EDC 射频接收IC TH71082EDC 射频接收IC TH7108EFC 射频接收IC TH71101ENE 射频接收IC TH71102ENE 射频接收IC TH71111ENE 射频接收IC TH71112ENE 射频接收IC TH71221ELQ 射频接收IC TH7122ENE 射频收发IC TH72001KDC 射频发射IC TH72002KDC 射频发射IC TH72005KLD 射频发射IC TH72006KLD 射频发射IC TH72011KDC 射频发射IC TH72012KDC 射频发射IC TH72015KLD 射频发射IC TH72016KLD 射频发射IC TH72031KDC 射频发射IC TH72032KDC 射频发射IC TH72035KLD 射频发射IC TH72036KLD 射频发射IC MICRF102BM 无线发射IC MICRF112YMM 无线发射IC MICRF113YM6 无线发射IC MICRF302YML 射频编码器MICRF405YML 射频发射IC MICRF505BML 射频收发IC MICRF506BML 射频收发IC MICRF002YM 射频接收器MICRF005YM 无线接收IC MICRF007BM UHF接收器MICRF008BM 无线接收IC MICRF009BM UHF接收IC MICRF010BM UHF接收IC MICRF011BM 射频ICMICRF211AYQS 射频接收器MRF24J40-I/ML ZigBee芯片MRF24J40T-I/ML ZigBee芯片MCP2030-I/P 免钥登录芯片MCP2030-I/SL 免钥登录芯片MCP2030-I/ST 免钥登录芯片MCP2030T-I/SL 免钥登录芯片MCP2030T-I/ST 免钥登录芯片nRF2401AG 2.4GHz收发器IC nRF24AP1 2.4GHz收发器IC nRF24E1G 2.4GHz收发器IC nRF24E2G 2.4GHz发射器IC nRF24L01+ 2.4GHz收发器IC nRF24LE1 2.4GHz收发器IC nRF24LU1 2.4GHz收发器IC nRF24Z1 2.4GHz收发器ICNRF905 430 928MHz收发器NRF9E5 430-928MHz收发器MFRC50001T/0FE,112 阅读器IC MFRC53001T/0FE,112 阅读器IC MFRC53101T/0FE,112 阅读器IC MFRC52301HN1 阅读器ICPN5110A0HN1/C2 收发器ICPN5120A0HN1/C1 收发器ICPN5310A3HN/C203 NFC控制器IC PN1000 GPS RF接收ICRX3400 射频接收ICRX3930 射频接收ICRX3140 射频接收ICRX3310A 射频接收ICRX3361 射频接收ICRX3408 射频接收ICPT4301 射频接收ICPT4316 射频接收ICPT4450 射频发射ICTX4915 射频发射ICTX4930 射频发射ICPA2460 功率放大器ICPA2464 功率放大器ICFS8107E 锁相环ICFS8108 锁相环ICFS8160 锁相环ICFS8170 锁相环ICFS8308 锁相环ICMG2400-F48 ZigBee单芯片MG2450-B72 ZigBee单芯片MG2455-F48 ZigBee单芯片AP1092 功率放大器ICAP1098 功率放大器ICAP1110 功率放大器ICAP1091 功率放大器ICAP1093 功率放大器ICAP1280 PA/LNA功率放大器AP1213 射频前端模块AP1290 功率放大器ICAP1291 功率放大器ICAP1294 功率放大器ICAP1045 功率放大器ICAP1046 功率放大器ICAP2085 功率放大器ICAP2010C 功率放大器ICAP3011 功率放大器ICAP3013 功率放大器ICAP3014 功率放大器ICAP3015 功率放大器ICAP3211 功率放大器ICSX1211I084TRT 单芯片收发器SX1441I077TRLF 系统蓝牙芯片XE1203FI063TRLF 射频收发芯片XE1205I074TRLF 射频收发芯片XE1283I076TRLF 射频收发芯片XM1203FC433XE1 射频收发芯片XM1203FC868XE1 射频收发芯片XM1203FC915XE1 射频收发芯片SX1223I073TRT 射频发射芯片SI3400-E1-GM 以太网电源ICSI3401-E1-GM 以太网电源ICSI3460-D01-GM 以太网电源ICSI4020-I1-FT 射频发射ICSI4021-A1-FT 射频发射ICSI4022-A1-FT 射频发射ICSI4030-A0-FM 射频发射ICSI4031-A0-FM 射频发射ICSI4032-V2-FM 射频发射ICSi4230-A0-FMIA4230 无线发射IC Si4231-A0-FMIA4231 无线发射IC Si4232-A0-FMIA4232 无线发射IC Si4320-J1-FT 无线接收ICSi4322-A1-FT 无线接收ICSi4330-V2-FMIA4330 无线接收IC SI4420-D1-FT 射频收发ICSI4421-A1-FTIA4421 无线收发IC SI4430-A0-FMIA4430 无线收发IC SI4431-A0-FMIA4431 无线收发IC SI4432-V2-FMIA4432 无线收发IC TM1001 功率放大器ICTM1006 功率放大器ICTM1008 射频晶体管TM3001 射频开关ICTM3002 射频开关ICTM4001 FM发射ICUW2453 无线网络ICUZ2400 ZigBee 芯片UP2206 2.4GHz功率放大器UP2268 2.4GHz功率放大器UA2707 射频信号放大器UA2709 射频信号放大器UA2711 射频信号放大器UA2712 射频信号放大器UA2715 射频信号放大器UA2716 射频信号放大器UA2725 射频信号放大器UA2731 射频信号放大器UA2732 射频信号放大器W2805 无线视频ICW2801 无线音频IC。

无线SoC芯片(CC1010,nRF9E5,nRF24E1)对比分析本文来自: 原文网址：/info/commonIC/0073686.html随着网络及其通信技术的飞速发展，短距离无线通信以其抗干扰能力强、可靠性高、安全性好、受地理条件限制较少、安装施工简便灵活等特点，在许多领域都得到了广泛的应用。

无线SoC芯片(也称无线单片机)将微控制器、存储器、A/D转换器、需要的接口电路和无线收发芯片全部集成到一个非常小的芯片上，并具有通用频带、收发合一、低发射功率、高灵敏接收等优点，因而在当前短距离无线通信系统中的应用潜力十分巨大。

而采用内嵌8051的无线SoC芯片，一方面能继续使用8051微控制器已经发展成熟的各种应用软件资源。

另一方面，目前市面上流行的8051开发工具(如Keil C51)都可以用于这种芯片的软件开发。

在已经推出的几种以8051微控制器为内核的无线SoC芯片中。

最具有代表性的是chipcon公司的CC1010、Nordic公司的nRF9E5和nRF24E1。

本文将对这三款无线SoC芯片作以对比描述，同时分析一下它们各自的结构原理、特性及典型应用电路1 CC1010无线SoC芯片CC1010是Chipcon公司推出的单片、多频段、低功耗的系统级无线射频收发芯片。

该芯片基于Chipcon公司的0.35 um CMOS工艺生产，具有很高的集成度该芯片内嵌8051微控制器，并包含32 KB Flash、2048+128字节SRAM、3通道10位ADC以及加密/解密用的DES模块。

发射器采用直接变频发射，接收器采用低-中变频接收。

CC1010通过8位控制寄存器RFMAIN来实现无线收发控制，不同工作频率(315-915 MHz)的应用电路可通过调节元器件C31～C181、L32～L101和R131等参数值来实现外接晶体必须连接到芯片的XOSC端，同时VCO也需要外接一个外部电感。

CC1010的典型应用电路如图1所示。