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NRF24L01P-R

NRF24L01P-R

  • 厂商:

    NORDIC(北欧)

  • 封装:

    QFN20_4X4MM_EP

  • 描述:

    2.4G无线芯片 1.9V~3.6V QFN20_4X4MM

  • 数据手册
  • 价格&库存
NRF24L01P-R 数据手册
nRF24L01+ Single Chip 2.4GHz Transceiver Product Specification v1.0 Key Features • • • • • • • • • • • • • • • • • • • Worldwide 2.4GHz ISM band operation 250kbps, 1Mbps and 2Mbps on air data rates Ultra low power operation 11.3mA TX at 0dBm output power 13.5mA RX at 2Mbps air data rate 900nA in power down 26µA in standby-I On chip voltage regulator 1.9 to 3.6V supply range Enhanced ShockBurst™ Automatic packet handling Auto packet transaction handling 6 data pipe MultiCeiver™ Drop-in compatibility with nRF24L01 On-air compatible in 250kbps and 1Mbps with nRF2401A, nRF2402, nRF24E1 and nRF24E2 Low cost BOM ±60ppm 16MHz crystal 5V tolerant inputs Compact 20-pin 4x4mm QFN package Applications • • • • • • • • • • • • • Wireless PC Peripherals Mouse, keyboards and remotes 3-in-1 desktop bundles Advanced Media center remote controls VoIP headsets Game controllers Sports watches and sensors RF remote controls for consumer electronics Home and commercial automation Ultra low power sensor networks Active RFID Asset tracking systems Toys All rights reserved. Reproduction in whole or in part is prohibited without the prior written permission of the copyright holder. September 2008 nRF24L01+ Product Specification Liability disclaimer Nordic Semiconductor ASA reserves the right to make changes without further notice to the product to improve reliability, function or design. Nordic Semiconductor ASA does not assume any liability arising out of the application or use of any product or circuits described herein. All application information is advisory and does not form part of the specification. Limiting values Stress above one or more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation of the device at these or at any other conditions above those given in the specifications are not implied. Exposure to limiting values for extended periods may affect device reliability. Life support applications These products are not designed for use in life support appliances, devices, or systems where malfunction of these products can reasonably be expected to result in personal injury. Nordic Semiconductor ASA customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify Nordic Semiconductor ASA for any damages resulting from such improper use or sale. Data sheet status Objective product specification This product specification contains target specifications for product development. Preliminary product specification This product specification contains preliminary data; supplementary data may be published from Nordic Semiconductor ASA later. Product specification This product specification contains final product specifications. Nordic Semiconductor ASA reserves the right to make changes at any time without notice in order to improve design and supply the best possible product. Contact details Visit www.nordicsemi.no for Nordic Semiconductor sales offices and distributors worldwide Main office: Otto Nielsens vei 12 7004 Trondheim Phone: +47 72 89 89 00 Fax: +47 72 89 89 89 www.nordicsemi.no Revision 1.0 Page 2 of 78 nRF24L01+ Product Specification Writing Conventions This product specification follows a set of typographic rules that makes the document consistent and easy to read. The following writing conventions are used: • Commands, bit state conditions, and register names are written in Courier. • Pin names and pin signal conditions are written in Courier bold. • Cross references are underlined and highlighted in blue. Revision History Date September 2008 Version 1.0 Description Attention! Observe precaution for handling Electrostatic Sensitive Device. HBM (Human Body Model) > 1Kv MM (Machine Model) > 200V Revision 1.0 Page 3 of 78 nRF24L01+ Product Specification Contents 1 1.1 1.2 2 2.1 2.2 3 4 5 5.1 5.2 5.3 5.4 5.5 5.6 5.7 6 6.1 6.1.1 6.1.2 6.1.3 6.1.4 6.1.5 6.1.6 6.1.7 6.2 6.3 6.4 6.5 6.6 7 7.1 7.2 7.3 7.3.1 7.3.2 7.3.3 7.3.4 7.3.5 7.3.6 7.3.7 7.4 7.4.1 7.4.2 Introduction ............................................................................................... Features ............................................................................................... Block diagram ...................................................................................... Pin Information.......................................................................................... Pin assignment..................................................................................... Pin functions......................................................................................... Absolute maximum ratings ...................................................................... Operating conditions ................................................................................ Electrical specifications ........................................................................... Power consumption.............................................................................. General RF conditions ......................................................................... Transmitter operation ........................................................................... Receiver operation ............................................................................... Crystal specifications ........................................................................... DC characteristics ................................................................................ Power on reset ..................................................................................... Radio Control ............................................................................................ Operational Modes............................................................................... State diagram .................................................................................. Power Down Mode .......................................................................... Standby Modes................................................................................ RX mode.......................................................................................... TX mode .......................................................................................... Operational modes configuration..................................................... Timing Information ........................................................................... Air data rate.......................................................................................... RF channel frequency .......................................................................... Received Power Detector measurements............................................ PA control............................................................................................. RX/TX control ....................................................................................... Enhanced ShockBurst™ .......................................................................... Features ............................................................................................... Enhanced ShockBurst™ overview ....................................................... Enhanced Shockburst™ packet format................................................ Preamble ......................................................................................... Address ........................................................................................... Packet control field .......................................................................... Payload............................................................................................ CRC (Cyclic Redundancy Check) ................................................... Automatic packet assembly ............................................................. Automatic packet disassembly ........................................................ Automatic packet transaction handling ................................................ Auto acknowledgement ................................................................... Auto Retransmission (ART) ............................................................. Revision 1.0 Page 4 of 78 7 8 9 10 10 11 12 13 14 14 15 15 16 19 20 20 21 21 21 22 22 23 23 24 24 25 25 25 26 26 27 27 27 28 28 28 28 29 30 31 32 33 33 33 nRF24L01+ Product Specification 7.5 7.5.1 7.5.2 7.6 7.7 7.8 7.8.1 7.8.2 7.8.3 7.8.4 7.8.5 7.8.6 Enhanced ShockBurst flowcharts ........................................................ 35 PTX operation.................................................................................. 35 PRX operation ................................................................................. 37 MultiCeiver™........................................................................................ 39 Enhanced ShockBurst™ timing ........................................................... 42 Enhanced ShockBurst™ transaction diagram ..................................... 45 Single transaction with ACK packet and interrupts.......................... 45 Single transaction with a lost packet ............................................... 46 Single transaction with a lost ACK packet ....................................... 46 Single transaction with ACK payload packet ................................... 47 Single transaction with ACK payload packet and lost packet .......... 47 Two transactions with ACK payload packet and the first ACK packet lost .............................................................................. 48 7.8.7 Two transactions where max retransmissions is reached ............... 48 7.9 Compatibility with ShockBurst™ .......................................................... 49 7.9.1 ShockBurst™ packet format ............................................................ 49 8 Data and Control Interface ....................................................................... 50 8.1 Features ............................................................................................... 50 8.2 Functional description .......................................................................... 50 8.3 SPI operation ....................................................................................... 50 8.3.1 SPI commands ................................................................................ 50 8.3.2 SPI timing ........................................................................................ 52 8.4 Data FIFO ............................................................................................ 55 8.5 Interrupt ................................................................................................ 56 9 Register Map.............................................................................................. 57 9.1 Register map table ............................................................................... 57 10 Peripheral RF Information ........................................................................ 64 10.1 Antenna output ..................................................................................... 64 10.2 Crystal oscillator ................................................................................... 64 10.3 nRF24L01+ crystal sharing with an MCU............................................. 64 10.3.1 Crystal parameters .......................................................................... 64 10.3.2 Input crystal amplitude and current consumption ............................ 64 10.4 PCB layout and decoupling guidelines................................................. 65 11 Application example ................................................................................. 66 11.1 PCB layout examples ........................................................................... 67 12 Mechanical specifications........................................................................ 71 13 Ordering information ................................................................................ 73 13.1 Package marking ................................................................................. 73 13.2 Abbreviations ....................................................................................... 73 13.3 Product options .................................................................................... 73 13.3.1 RF silicon ......................................................................................... 73 13.3.2 Development tools ........................................................................... 73 14 Glossary of Terms..................................................................................... 74 Appendix A - Enhanced ShockBurst™ - Configuration and communication example ......................................................................... 75 Enhanced ShockBurst™ transmitting payload ..................................... 75 Revision 1.0 Page 5 of 78 nRF24L01+ Product Specification Enhanced ShockBurst™ receive payload ............................................ Appendix B - Configuration for compatibility with nRF24XX................ Appendix C - Constant carrier wave output for testing......................... Configuration ........................................................................................ Revision 1.0 Page 6 of 78 76 77 78 78 nRF24L01+ Product Specification 1 Introduction The nRF24L01+ is a single chip 2.4GHz transceiver with an embedded baseband protocol engine (Enhanced ShockBurst™), suitable for ultra low power wireless applications. The nRF24L01+ is designed for operation in the world wide ISM frequency band at 2.400 - 2.4835GHz. To design a radio system with the nRF24L01+, you simply need an MCU (microcontroller) and a few external passive components. You can operate and configure the nRF24L01+ through a Serial Peripheral Interface (SPI). The register map, which is accessible through the SPI, contains all configuration registers in the nRF24L01+ and is accessible in all operation modes of the chip. The embedded baseband protocol engine (Enhanced ShockBurst™) is based on packet communication and supports various modes from manual operation to advanced autonomous protocol operation. Internal FIFOs ensure a smooth data flow between the radio front end and the system’s MCU. Enhanced ShockBurst™ reduces system cost by handling all the high speed link layer operations. The radio front end uses GFSK modulation. It has user configurable parameters like frequency channel, output power and air data rate. nRF24L01+ supports an air data rate of 250 kbps, 1 Mbps and 2Mbps. The high air data rate combined with two power saving modes make the nRF24L01+ very suitable for ultra low power designs. nRF24L01+ is drop-in compatible with nRF24L01 and on-air compatible with nRF2401A, nRF2402, nRF24E1 and nRF24E2. Intermodulation and wideband blocking values in nRF24L01+ are much improved in comparison to the nRF24L01 and the addition of internal filtering to nRF24L01+ has improved the margins for meeting RF regulatory standards. Internal voltage regulators ensure a high Power Supply Rejection Ratio (PSRR) and a wide power supply range. Revision 1.0 Page 7 of 78 nRF24L01+ Product Specification 1.1 Features Features of the nRF24L01+ include: • • • • • • • • Radio X Worldwide 2.4GHz ISM band operation X 126 RF channels X Common RX and TX interface X GFSK modulation X 250kbps, 1 and 2Mbps air data rate X 1MHz non-overlapping channel spacing at 1Mbps X 2MHz non-overlapping channel spacing at 2Mbps Transmitter X Programmable output power: 0, -6, -12 or -18dBm X 11.3mA at 0dBm output power Receiver X Fast AGC for improved dynamic range X Integrated channel filters X 13.5mA at 2Mbps X -82dBm sensitivity at 2Mbps X -85dBm sensitivity at 1Mbps X -94dBm sensitivity at 250kbps RF Synthesizer X Fully integrated synthesizer X No external loop filer, VCO varactor diode or resonator X Accepts low cost ±60ppm 16MHz crystal Enhanced ShockBurst™ X 1 to 32 bytes dynamic payload length X Automatic packet handling X Auto packet transaction handling X 6 data pipe MultiCeiver™ for 1:6 star networks Power Management X Integrated voltage regulator X 1.9 to 3.6V supply range X Idle modes with fast start-up times for advanced power management X 26µA Standby-I mode, 900nA power down mode X Max 1.5ms start-up from power down mode X Max 130us start-up from standby-I mode Host Interface X 4-pin hardware SPI X Max 10Mbps X 3 separate 32 bytes TX and RX FIFOs X 5V tolerant inputs Compact 20-pin 4x4mm QFN package Revision 1.0 Page 8 of 78 nRF24L01+ Product Specification 1.2 Block diagram RF Transmitter PA Baseband TX Filter CSN TX FIFOs GFSK Modulator SPI LNA ANT2 Radio Control VDD_PA DVDD Power Management IREF RF Synthesiser VSS XC2 RX FIFOs VDD XC1 GFSK Demodulator Figure 1. nRF24L01+ block diagram Revision 1.0 Page 9 of 78 Register map ANT1 RX Filter MISO MOSI Enhanced ShockBurst Baseband Engine RF Receiver SCK IRQ CE nRF24L01+ Product Specification VDD VSS IREF Pin assignment DVDD 2.1 Pin Information VSS 2 20 19 18 17 16 CE 1 15 VDD CSN 2 14 VSS 13 ANT2 nRF24L01+ SCK 3 QFN20 4X4 5 11 VDD_PA 6 7 8 9 10 XC1 MISO XC2 ANT1 VSS 12 VDD 4 IRQ MOSI Figure 2. nRF24L01+ pin assignment (top view) for the QFN20 4x4 package Revision 1.0 Page 10 of 78 nRF24L01+ Product Specification 2.2 Pin functions Pin 1 2 3 4 5 6 7 8 9 10 11 Name CE CSN SCK MOSI MISO IRQ VDD VSS XC2 XC1 VDD_PA Pin function Digital Input Digital Input Digital Input Digital Input Digital Output Digital Output Power Power Analog Output Analog Input Power Output 12 13 14 15 16 ANT1 ANT2 VSS VDD IREF RF RF Power Power Analog Input 17 18 19 VSS VDD DVDD Power Power Power Output 20 VSS Power Description Chip Enable Activates RX or TX mode SPI Chip Select SPI Clock SPI Slave Data Input SPI Slave Data Output, with tri-state option Maskable interrupt pin. Active low Power Supply (+1.9V - +3.6V DC) Ground (0V) Crystal Pin 2 Crystal Pin 1 Power Supply Output (+1.8V) for the internal nRF24L01+ Power Amplifier. Must be connected to ANT1 and ANT2 as shown in Figure 32. Antenna interface 1 Antenna interface 2 Ground (0V) Power Supply (+1.9V - +3.6V DC) Reference current. Connect a 22kΩ resistor to ground. See Figure 32. Ground (0V) Power Supply (+1.9V - +3.6V DC) Internal digital supply output for de-coupling purposes. See Figure 32. Ground (0V) Table 1. nRF24L01+ pin function Revision 1.0 Page 11 of 78 nRF24L01+ Product Specification 3 Absolute maximum ratings Note: Exceeding one or more of the limiting values may cause permanent damage to nRF24L01+. Operating conditions Supply voltages VDD VSS Input voltage VI Output voltage VO Total Power Dissipation PD (TA=85°C) Temperatures Operating Temperature Storage Temperature Minimum Maximum Units -0.3 3.6 0 V V -0.3 5.25 V VSS to VDD VSS to VDD -40 -40 Table 2. Absolute maximum ratings Revision 1.0 Page 12 of 78 60 mW +85 +125 °C °C nRF24L01+ Product Specification 4 Operating conditions Symbol Parameter (condition) VDD Supply voltage Supply voltage if input signals >3.6V VDD TEMP Operating Temperature Notes Table 3. Operating conditions Revision 1.0 Page 13 of 78 Min. 1.9 2.7 -40 Typ. 3.0 3.0 +27 Max. Units 3.6 V 3.3 V +85 ºC nRF24L01+ Product Specification 5 Electrical specifications Conditions: VDD = +3V, VSS = 0V, TA = - 40ºC to + 85ºC 5.1 Power consumption Symbol IVDD_PD IVDD_ST1 IVDD_ST2 IVDD_SU IVDD_TX0 IVDD_TX6 IVDD_TX12 IVDD_TX18 IVDD_AVG IVDD_TXS IVDD_2M IVDD_1M IVDD_250 IVDD_RXS Parameter (condition) Notes Idle modes Supply current in power down a Supply current in standby-I mode Supply current in standby-II mode Average current during 1.5ms crystal oscillator startup Transmit b Supply current @ 0dBm output power b Supply current @ -6dBm output power b Supply current @ -12dBm output power b Supply current @ -18dBm output power c Average Supply current @ -6dBm output power, ShockBurst™ d Average current during TX settling Receive Supply current 2Mbps Supply current 1Mbps Supply current 250kbps e Average current during RX settling Min. a. b. c. d. Typ. Max. 900 26 320 400 nA µA µA µA 11.3 9.0 mA mA 7.5 mA 7.0 mA 0.12 mA 8.0 mA 13.5 13.1 12.6 8.9 mA mA mA mA This current is for a 12pF crystal. Current when using external clock is dependent on signal swing. Antenna load impedance = 15Ω+j88Ω.. Antenna load impedance = 15Ω+j88Ω. Average data rate 10kbps and max. payload length packets. Average current consumption during TX startup (130µs) and when changing mode from RX to TX (130µs). e. Average current consumption during RX startup (130µs) and when changing mode from TX to RX (130µs). Table 4. Power consumption Revision 1.0 Page 14 of 78 Units nRF24L01+ Product Specification 5.2 General RF conditions Symbol fOP PLLres fXTAL Δf250 Δf1M Δf2M RGFSK Parameter (condition) Notes a Operating frequency PLL Programming resolution Crystal frequency Frequency deviation @ 250kbps Frequency deviation @ 1Mbps Frequency deviation @ 2Mbps b Air Data rate c FCHANNEL 1M Non-overlapping channel spacing @ 250kbps/ 1Mbps c FCHANNEL 2M Non-overlapping channel spacing @ 2Mbps Min. 2400 Typ. Max. 2525 1 Units MHz MHz MHz kHz kHz kHz kbps MHz 2 MHz 1 16 ±160 ±160 ±320 250 2000 a. Regulatory standards determine the band range you can use. b. Data rate in each burst on-air c. The minimum channel spacing is 1MHz Table 5. General RF conditions 5.3 Transmitter operation Symbol PRF PRFC PRFCR PBW2 PBW1 PBW250 PRF1.2 PRF2.2 PRF1.1 PRF2.1 PRF1.250 PRF2.250 Parameter (condition) Notes Min. a Maximum Output Power RF Power Control Range 16 RF Power Accuracy 20dB Bandwidth for Modulated Carrier (2Mbps) 20dB Bandwidth for Modulated Carrier (1Mbps) 20dB Bandwidth for Modulated Carrier (250kbps) 1st Adjacent Channel Transmit Power 2MHz (2Mbps) 2nd Adjacent Channel Transmit Power 4MHz (2Mbps) 1st Adjacent Channel Transmit Power 1MHz (1Mbps) 2nd Adjacent Channel Transmit Power 2MHz (1Mbps) 1st Adjacent Channel Transmit Power 1MHz (250kbps) 2nd Adjacent Channel Transmit Power 2MHz (250kbps) a. Antenna load impedance = 15Ω+j88Ω Table 6. Transmitter operation Revision 1.0 Page 15 of 78 Typ. 0 18 1800 900 700 Max. +4 20 ±4 2000 1000 800 -20 Units dBm dB dB kHz kHz kHz dBc -50 dBc -20 dBc -45 dBc -30 dBc -45 dBc nRF24L01+ Product Specification 5.4 Receiver operation Datarate Symbol RXmax RXSENS RXSENS RXSENS 2Mbps 1Mbps 250kbps Parameter (condition) Notes Min. Maximum received signal at 12MHz i C/INth Nth ACS C/I, f > 36MHz i C/ICO C/I Co-channel C/I1ST 1st ACS C/I 1MHz C/I2ND 2nd ACS C/I 2MHz C/I3RD 3rd ACS C/I 3MHz C/INth Nth ACS C/I, f > 6MHz a C/INth Nth ACS C/I, f > 25MHz i 250kbps C/ICO C/I Co-channel C/I1ST 1st ACS C/I 1MHz C/I2ND 2nd ACS C/I 2MHz C/I3RD 3rd ACS C/I 3MHz C/INth Nth ACS C/I, f > 6MHz a C/INth Nth ACS C/I, f > 25MHz i a 1Mbps i i Typ. Max. Units 7 dBc 3 dBc -17 dBc -21 dBc -40 dBc -48 dBc 9 8 -20 -30 -40 dBc dBc dBc dBc dBc -47 dBc 12 -12 -33 -38 -50 dBc dBc dBc dBc dBc -60 dBc a. Narrow Band (In Band) Blocking measurements: 0 to ±40MHz; 1MHz step size For Interferer frequency offsets n*2*fxtal, blocking performance is degraded by approximately 5dB compared to adjacent figures. Table 8. RX selectivity according to ETSI EN 300 440-1 V1.3.1 (2001-09) page 27 Revision 1.0 Page 16 of 78 nRF24L01+ Product Specification Datarate 2Mbps Symbol C/ICO C/I1ST C/I2ND C/I3RD C/INth C/INth 1Mbps C/ICO C/I1ST C/I2ND C/I3RD C/INth C/INth 250kbps C/ICO C/I1ST C/I2ND C/I3RD C/INth C/INth Parameter (condition) C/I Co-channel (Modulated carrier) Notes Min. 1st ACS C/I 2MHz 2nd ACS C/I 4MHz 3rd ACS C/I 6MHz Nth ACS C/I, fi > 12MHz Nth ACS C/I, fi > 36MHz C/I Co-channel a st 1 ACS C/I 1MHz 2nd ACS C/I 2MHz 3rd ACS C/I 3MHz Nth ACS C/I, fi > 6MHz Nth ACS C/I, fi > 25MHz C/I Co-channel a 1st ACS C/I 1MHz 2nd ACS C/I 2MHz 3rd ACS C/I 3MHz Nth ACS C/I, fi >6MHz Nth ACS C/I, fi >25MHz a Typ. 11 4 -18 -24 -40 Max. Units dBc dBc dBc dBc dBc -48 dBc 12 8 -21 -30 -40 dBc dBc dBc dBc dBc -50 dBc 7 -12 -34 -39 -50 dBc dBc dBc dBc dBc -60 dBc a. Narrow Band (In Band) Blocking measurements: 0 to ±40MHz; 1MHz step size Wide Band Blocking measurements: 30MHz to 2000MHz; 10MHz step size 2000MHz to 2399MHz; 3MHz step size 2484MHz to 3000MHz; 3MHz step size 3GHz to 12.75GHz; 25MHz step size Wanted signal for wideband blocking measurements: -67dBm in 1Mbps and 2Mbps mode -77dBm in 250kbps mode For Interferer frequency offsets n*2*fxtal, blocking performance are degraded by approximately 5dB compared to adjacent figures. If the wanted signal is 3dB or more above the sensitivity level then, the carrier/interferer ratio is independent of the wanted signal level for a given frequency offset. Table 9. RX selectivity with nRF24L01+ equal modulation on interfering signal. Measured using Pin = -67dBm for wanted signal. Revision 1.0 Page 17 of 78 nRF24L01+ Product Specification Datarate Symbol Parameter (condition) Notes Min. Typ. Max. Units 2Mbps P_IM(6 Input power of IM interferers at 6 and 12MHz offset -42 dBm from wanted signal P_IM(8) Input power of IM interferers at 8 and 16MHz offset -38 dBm from wanted signal P_IM(10) Input power of IM interferers at 10 and 20MHz offset -37 dBm from wanted signal 1Mbps P_IM(3) Input power of IM interferers at 3 and 6MHz offset -36 dBm from wanted signal P_IM(4) Input power of IM interferers at 4 and 8MHz offset -36 dBm from wanted signal P_IM(5) Input power of IM interferers at 5 and 10MHz offset -36 dBm from wanted signal 250kbps P_IM(3) Input power of IM interferers at 3 and 6MHz offset -36 dBm from wanted signal P_IM(4) Input power of IM interferers at 4 and 8MHz offset -36 dBm from wanted signal P_IM(5) Input power of IM interferers at 5 and 10MHz offset -36 dBm from wanted signal Note: Wanted signal level at Pin = -64 dBm. Two interferers with equal input power are used. The interferer closest in frequency is unmodulated, the other interferer is modulated equal with the wanted signal. The input power of interferers where the sensitivity equals BER = 0.1% is presented. Table 10. RX intermodulation test performed according to Bluetooth Specification version 2.0 Revision 1.0 Page 18 of 78 nRF24L01+ Product Specification 5.5 Crystal specifications Symbol Fxo ΔF C0 Ls CL ESR Parameter (condition) Crystal Frequency Tolerance Equivalent parallel capacitance Equivalent serial inductance Load capacitance Equivalent Series Resistance Notes Min. Typ. 16 ab c 8 1.5 30 12 Max. ±60 7.0 16 100 Units MHz ppm pF mH pF Ω a. Frequency accuracy including; tolerance at 25ºC, temperature drift, aging and crystal loading. b. Frequency regulations in certain regions set tighter requirements for frequency tolerance (For example, Japan and South Korea specify max. +/- 50ppm). c. Startup time from power down to standby mode is dependant on the Ls parameter. See Table 16. on page 24 for details. Table 11. Crystal specifications The crystal oscillator startup time is proportional to the crystal equivalent inductance. The trend in crystal design is to reduce the physical outline. An effect of a small outline is an increase in equivalent serial inductance Ls, which gives a longer startup time. The maximum crystal oscillator startup time, Tpd2stby = 1.5 ms, is set using a crystal with equivalent serial inductance of maximum 30mH. An application specific worst case startup time can be calculated as : Tpd2stby= Ls/30mH *1.5ms if Ls exceeds 30mH. Note: In some crystal datasheets Ls is called L1 or Lm and Cs is called C1 or Cm. Co ESR Cs Ls Figure 3. Equivalent crystal components Revision 1.0 Page 19 of 78 nRF24L01+ Product Specification 5.6 DC characteristics Symbol VIH VIL Parameter (condition) HIGH level input voltage LOW level input voltage Notes Min. 0.7VDD VSS Typ. Max. Units V 0.3VDD V 5.25a a. If the input signal >3.6V, the VDD of the nRF24L01+ must be between 2.7V and 3.3V (3.0V±10%) Table 12. Digital input pin Symbol VOH VOL Parameter (condition) HIGH level output voltage (IOH=-0.25mA) LOW level output voltage (IOL=0.25mA) Notes Min. VDD -0.3 Typ. Max. VDD 0.3 Units V V Max. 100 100 Units ms ms Table 13. Digital output pin 5.7 Power on reset Symbol TPUP TPOR Parameter (condition) Power ramp up time Power on reset Notes Min. a b a. From 0V to 1.9V. b. Measured from when the VDD reaches 1.9V to when the reset finishes. Table 14. Power on reset Revision 1.0 Page 20 of 78 1 Typ. nRF24L01+ Product Specification 6 Radio Control This chapter describes the nRF24L01+ radio transceiver’s operating modes and the parameters used to control the radio. The nRF24L01+ has a built-in state machine that controls the transitions between the chip’s operating modes. The state machine takes input from user defined register values and internal signals. 6.1 Operational Modes You can configure the nRF24L01+ in power down, standby, RX or TX mode. This section describes these modes in detail. 6.1.1 State diagram The state diagram in Figure 4. shows the operating modes and how they function. There are three types of distinct states highlighted in the state diagram: • • • Recommended operating mode: is a recommended state used during normal operation. Possible operating mode: is a possible operating state, but is not used during normal operation. Transition state: is a time limited state used during start up of the oscillator and settling of the PLL. When the VDD reaches 1.9V or higher nRF24L01+ enters the Power on reset state where it remains in reset until entering the Power Down mode. Revision 1.0 Page 21 of 78 nRF24L01+ Product Specification . Legend: Undefined Undefined Undefined VDD >= 1.9V Recommended operating mode Power on reset 100ms Possible operating mode Transition state Recommended path between operating modes Crystal oscillator start up Tpd2stby Power Down Possible path between operating modes CE = 1 Pin signal condition PWR_DN = 1 Bit state condition TX FIFO empty PWR_UP=0 PWR_UP = 1 System information PWR_UP=0 PWR_UP = 0 PRIM_RX = 0 TX FIFO empty CE = 1 Standby-I PWR_UP = 0 CE = 0 RX Settling 130 µs PRIM_RX = 1 CE = 1 Standby-II TX FIFO not empty PRIM_RX = 0 CE = 1 for more than 10µs TX finished with one packet CE = 0 CE = 0 TX FIFO not empty CE = 1 TX Settling 130 µs RX Mode TX FIFO empty CE = 1 PWR_UP=0 TX Mode PWR_UP = 0 CE = 1 TX FIFO not empty Figure 4. Radio control state diagram 6.1.2 Power Down Mode In power down mode nRF24L01+ is disabled using minimal current consumption. All register values available are maintained and the SPI is kept active, enabling change of configuration and the uploading/downloading of data registers. For start up times see Table 16. on page 24. Power down mode is entered by setting the PWR_UP bit in the CONFIG register low. 6.1.3 Standby Modes 6.1.3.1 Standby-I mode By setting the PWR_UP bit in the CONFIG register to 1, the device enters standby-I mode. Standby-I mode is used to minimize average current consumption while maintaining short start up times. In this mode only part of the crystal oscillator is active. Change to active modes only happens if CE is set high and when CE is set low, the nRF24L01 returns to standby-I mode from both the TX and RX modes. Revision 1.0 Page 22 of 78 nRF24L01+ Product Specification 6.1.3.2 Standby-II mode In standby-II mode extra clock buffers are active and more current is used compared to standby-I mode. nRF24L01+ enters standby-II mode if CE is held high on a PTX device with an empty TX FIFO. If a new packet is uploaded to the TX FIFO, the PLL immediately starts and the packet is transmitted after the normal PLL settling delay (130µs). Register values are maintained and the SPI can be activated during both standby modes. For start up times see Table 16. on page 24. 6.1.4 RX mode The RX mode is an active mode where the nRF24L01+ radio is used as a receiver. To enter this mode, the nRF24L01+ must have the PWR_UP bit, PRIM_RX bit and the CE pin set high. In RX mode the receiver demodulates the signals from the RF channel, constantly presenting the demodulated data to the baseband protocol engine. The baseband protocol engine constantly searches for a valid packet. If a valid packet is found (by a matching address and a valid CRC) the payload of the packet is presented in a vacant slot in the RX FIFOs. If the RX FIFOs are full, the received packet is discarded. The nRF24L01+ remains in RX mode until the MCU configures it to standby-I mode or power down mode. However, if the automatic protocol features (Enhanced ShockBurst™) in the baseband protocol engine are enabled, the nRF24L01+ can enter other modes in order to execute the protocol. In RX mode a Received Power Detector (RPD) signal is available. The RPD is a signal that is set high when a RF signal higher than -64 dBm is detected inside the receiving frequency channel. The internal RPD signal is filtered before presented to the RPD register. The RF signal must be present for at least 40µs before the RPD is set high. How to use the RPD is described in Section 6.4 on page 25. 6.1.5 TX mode The TX mode is an active mode for transmitting packets. To enter this mode, the nRF24L01+ must have the PWR_UP bit set high, PRIM_RX bit set low, a payload in the TX FIFO and a high pulse on the CE for more than 10µs. The nRF24L01+ stays in TX mode until it finishes transmitting a packet. If CE = 0, nRF24L01+ returns to standby-I mode. If CE = 1, the status of the TX FIFO determines the next action. If the TX FIFO is not empty the nRF24L01+ remains in TX mode and transmits the next packet. If the TX FIFO is empty the nRF24L01+ goes into standby-II mode. The nRF24L01+ transmitter PLL operates in open loop when in TX mode. It is important never to keep the nRF24L01+ in TX mode for more than 4ms at a time. If the Enhanced ShockBurst™ features are enabled, nRF24L01+ is never in TX mode longer than 4ms. Revision 1.0 Page 23 of 78 nRF24L01+ Product Specification 6.1.6 Operational modes configuration The following table (Table 15.) describes how to configure the operational modes. RX mode TX mode PWR_UP register 1 1 PRIM_RX register 1 0 TX mode 1 0 Standby-II Standby-I Power Down 1 1 0 0 - Mode CE input pin FIFO state 1 1 Data in TX FIFOs. Will empty all levels in TX FIFOsa. Minimum 10µs Data in TX FIFOs.Will empty one high pulse level in TX FIFOsb. 1 TX FIFO empty. 0 No ongoing packet transmission. - a. If CE is held high all TX FIFOs are emptied and all necessary ACK and possible retransmits are carried out. The transmission continues as long as the TX FIFO is refilled. If the TX FIFO is empty when the CE is still high, nRF24L01+ enters standby-II mode. In this mode the transmission of a packet is started as soon as the CSN is set high after an upload (UL) of a packet to TX FIFO. b. This operating mode pulses the CE high for at least 10µs. This allows one packet to be transmitted. This is the normal operating mode. After the packet is transmitted, the nRF24L01+ enters standby-I mode. Table 15. nRF24L01+ main modes 6.1.7 Timing Information The timing information in this section relates to the transitions between modes and the timing for the CE pin. The transition from TX mode to RX mode or vice versa is the same as the transition from the standby modes to TX mode or RX mode (max. 130µs), as described in Table 16. Name nRF24L01+ Notes Tpd2stby Power Down Î Standby mode a Tstby2a Standby modes Î TX/RX mode Thce Minimum CE high Tpece2csn Delay from CE positive edge to CSN low Max. 150µs 1.5ms 3ms 4.5ms 130µs Min. Comments With external clock External crystal, Ls < 30mH External crystal, Ls = 60mH External crystal, Ls = 90mH 10µs 4µs a. See Table 11. on page 19 for crystal specifications. Table 16. Operational timing of nRF24L01+ For nRF24L01+ to go from power down mode to TX or RX mode it must first pass through stand-by mode. There must be a delay of Tpd2stby (see Table 16.) after the nRF24L01+ leaves power down mode before the CE is set high. Note: If VDD is turned off the register value is lost and you must configure nRF24L01+ before entering the TX or RX modes. Revision 1.0 Page 24 of 78 nRF24L01+ Product Specification 6.2 Air data rate The air data rate is the modulated signaling rate the nRF24L01+ uses when transmitting and receiving data. It can be 250kbps, 1Mbps or 2Mbps. Using lower air data rate gives better receiver sensitivity than higher air data rate. But, high air data rate gives lower average current consumption and reduced probability of on-air collisions. The air data rate is set by the RF_DR bit in the RF_SETUP register. A transmitter and a receiver must be programmed with the same air data rate to communicate with each other. nRF24L01+ is fully compatible with nRF24L01. For compatibility with nRF2401A, nRF2402, nRF24E1, and nRF24E2 the air data rate must be set to 250kbps or 1Mbps. 6.3 RF channel frequency The RF channel frequency determines the center of the channel used by the nRF24L01+. The channel occupies a bandwidth of less than 1MHz at 250kbps and 1Mbps and a bandwidth of less than 2MHz at 2Mbps. nRF24L01+ can operate on frequencies from 2.400GHz to 2.525GHz. The programming resolution of the RF channel frequency setting is 1MHz. At 2Mbps the channel occupies a bandwidth wider than the resolution of the RF channel frequency setting. To ensure non-overlapping channels in 2Mbps mode, the channel spacing must be 2MHz or more. At 1Mbps and 250kbps the channel bandwidth is the same or lower than the resolution of the RF frequency. The RF channel frequency is set by the RF_CH register according to the following formula: F0= 2400 + RF_CH [MHz] You must program a transmitter and a receiver with the same RF channel frequency to communicate with each other. 6.4 Received Power Detector measurements Received Power Detector (RPD), located in register 09, bit 0, triggers at received power levels above -64 dBm that are present in the RF channel you receive on. If the received power is less than -64 dBm, RDP = 0. The RPD can be read out at any time while nRF24L01+ is in receive mode. This offers a snapshot of the current received power level in the channel. The RPD status is latched when a valid packet is received which then indicates signal strength from your own transmitter. If no packets are received the RPD is latched at the end of a receive period as a result of host MCU setting CE low or RX time out controlled by Enhanced ShockBurst™. The status of RPD is correct when RX mode is enabled and after a wait time of Tstby2a +Tdelay_AGC= 130us + 40us. The RX gain varies over temperature which means that the RPD threshold also varies over temperature. The RPD threshold value is reduced by - 5dB at T = -40°C and increased by + 5dB at 85°C. Revision 1.0 Page 25 of 78 nRF24L01+ Product Specification 6.5 PA control The PA (Power Amplifier) control is used to set the output power from the nRF24L01+ power amplifier. In TX mode PA control has four programmable steps, see Table 17. The PA control is set by the RF_PWR bits in the RF_SETUP register. SPI RF-SETUP RF output power (RF_PWR) 11 0dBm 10 -6dBm 01 -12dBm 00 -18dBm DC current consumption 11.3mA 9.0mA 7.5mA 7.0mA Conditions: VDD = 3.0V, VSS = 0V, TA = 27ºC, Load impedance = 15Ω+j88Ω. Table 17. RF output power setting for the nRF24L01+ 6.6 RX/TX control The RX/TX control is set by PRIM_RX bit in the CONFIG register and sets the nRF24L01+ in transmit/ receive mode. Revision 1.0 Page 26 of 78 nRF24L01+ Product Specification 7 Enhanced ShockBurst™ Enhanced ShockBurst™ is a packet based data link layer that features automatic packet assembly and timing, automatic acknowledgement and retransmissions of packets. Enhanced ShockBurst™ enables the implementation of ultra low power and high performance communication with low cost host microcontrollers. The Enhanced ShockBurst™ features enable significant improvements of power efficiency for bidirectional and uni-directional systems, without adding complexity on the host controller side. 7.1 Features The main features of Enhanced ShockBurst™ are: • • • • 7.2 1 to 32 bytes dynamic payload length Automatic packet handling Automatic packet transaction handling X Auto Acknowledgement with payload X Auto retransmit 6 data pipe MultiCeiver™ for 1:6 star networks Enhanced ShockBurst™ overview Enhanced ShockBurst™ uses ShockBurst™ for automatic packet handling and timing. During transmit, ShockBurst™ assembles the packet and clocks the bits in the data packet for transmission. During receive, ShockBurst™ constantly searches for a valid address in the demodulated signal. When ShockBurst™ finds a valid address, it processes the rest of the packet and validates it by CRC. If the packet is valid the payload is moved into a vacant slot in the RX FIFOs. All high speed bit handling and timing is controlled by ShockBurst™. Enhanced ShockBurst™ features automatic packet transaction handling for the easy implementation of a reliable bi-directional data link. An Enhanced ShockBurst™ packet transaction is a packet exchange between two transceivers, with one transceiver acting as the Primary Receiver (PRX) and the other transceiver acting as the Primary Transmitter (PTX). An Enhanced ShockBurst™ packet transaction is always initiated by a packet transmission from the PTX, the transaction is complete when the PTX has received an acknowledgment packet (ACK packet) from the PRX. The PRX can attach user data to the ACK packet enabling a bi-directional data link. The automatic packet transaction handling works as follows: 1. 2. 3. You begin the transaction by transmitting a data packet from the PTX to the PRX. Enhanced ShockBurst™ automatically sets the PTX in receive mode to wait for the ACK packet. If the packet is received by the PRX, Enhanced ShockBurst™ automatically assembles and transmits an acknowledgment packet (ACK packet) to the PTX before returning to receive mode. If the PTX does not receive the ACK packet immediately, Enhanced ShockBurst™ automatically retransmits the original data packet after a programmable delay and sets the PTX in receive mode to wait for the ACK packet. In Enhanced ShockBurst™ it is possible to configure parameters such as the maximum number of retransmits and the delay from one transmission to the next retransmission. All automatic handling is done without the involvement of the MCU. Revision 1.0 Page 27 of 78 nRF24L01+ Product Specification 7.3 Enhanced Shockburst™ packet format The format of the Enhanced ShockBurst™ packet is described in this section. The Enhanced ShockBurst™ packet contains a preamble, address, packet control, payload and CRC field. Figure 5. shows the packet format with MSB to the left. P re a m b le 1 b y te A d d re s s 3 -5 b y te P a c k e t C o n tro l F ie ld 9 b it P a y lo a d 0 - 3 2 b y te C R C 1 -2 b y te Figure 5. An Enhanced ShockBurst™ packet with payload (0-32 bytes) 7.3.1 Preamble The preamble is a bit sequence used to synchronize the receivers demodulator to the incoming bit stream. The preamble is one byte long and is either 01010101 or 10101010. If the first bit in the address is 1 the preamble is automatically set to 10101010 and if the first bit is 0 the preamble is automatically set to 01010101. This is done to ensure there are enough transitions in the preamble to stabilize the receiver. 7.3.2 Address This is the address for the receiver. An address ensures that the packet is detected and received by the correct receiver, preventing accidental cross talk between multiple nRF24L01+ systems. You can configure the address field width in the AW register to be 3, 4 or 5 bytes, see Table 28. on page 63. Note: Addresses where the level shifts only one time (that is, 000FFFFFFF) can often be detected in noise and can give a false detection, which may give a raised Packet Error Rate. Addresses as a continuation of the preamble (hi-low toggling) also raises the Packet Error Rate. 7.3.3 Packet control field Figure 6. shows the format of the 9 bit packet control field, MSB to the left. Payload length 6bit PID 2bit NO_ACK 1bit Figure 6. Packet control field The packet control field contains a 6 bit payload length field, a 2 bit PID (Packet Identity) field and a 1 bit NO_ACK flag. Revision 1.0 Page 28 of 78 nRF24L01+ Product Specification 7.3.3.1 Payload length This 6 bit field specifies the length of the payload in bytes. The length of the payload can be from 0 to 32 bytes. Coding: 000000 = 0 byte (only used in empty ACK packets.) 100000 = 32 byte, 100001 = Don’t care. This field is only used if the Dynamic Payload Length function is enabled. 7.3.3.2 PID (Packet identification) The 2 bit PID field is used to detect if the received packet is new or retransmitted. PID prevents the PRX device from presenting the same payload more than once to the receiving host MCU. The PID field is incremented at the TX side for each new packet received through the SPI. The PID and CRC fields (see section 7.3.5 on page 30) are used by the PRX device to determine if a packet is retransmitted or new. When several data packets are lost on the link, the PID fields may become equal to the last received PID. If a packet has the same PID as the previous packet, nRF24L01+ compares the CRC sums from both packets. If the CRC sums are also equal, the last received packet is considered a copy of the previously received packet and discarded. 7.3.3.3 No Acknowledgment flag (NO_ACK) The Selective Auto Acknowledgement feature controls the NO_ACK flag. This flag is only used when the auto acknowledgement feature is used. Setting the flag high tells the receiver that the packet is not to be auto acknowledged. On the PTX you can set the NO_ACK flag bit in the Packet Control Field with this command: W_TX_PAYLOAD_NOACK However, the function must first be enabled in the FEATURE register by setting the EN_DYN_ACK bit. When you use this option the PTX goes directly to standby-I mode after transmitting the packet. The PRX does not transmit an ACK packet when it receives the packet. 7.3.4 Payload The payload is the user defined content of the packet. It can be 0 to 32 bytes wide and is transmitted on-air when it is uploaded to nRF24L01+. Enhanced ShockBurst™ provides two alternatives for handling payload lengths; static and dynamic. The default is static payload length. With static payload length all packets between a transmitter and a receiver have the same length. Static payload length is set by the RX_PW_Px registers on the receiver side. The payload length on the transmitter side is set by the number of bytes clocked into the TX_FIFO and must equal the value in the RX_PW_Px register on the receiver side. Dynamic Payload Length (DPL) is an alternative to static payload length. DPL enables the transmitter to send packets with variable payload length to the receiver. This means that for a system with different payload lengths it is not necessary to scale the packet length to the longest payload. Revision 1.0 Page 29 of 78 nRF24L01+ Product Specification With the DPL feature the nRF24L01+ can decode the payload length of the received packet automatically instead of using the RX_PW_Px registers. The MCU can read the length of the received payload by using the R_RX_PL_WID command. Note: Always check if the packet width reported is 32 bytes or shorter when using the R_RX_PL_WID command. If its width is longer than 32 bytes then the packet contains errors and must be discarded. Discard the packet by using the Flush_RX command. In order to enable DPL the EN_DPL bit in the FEATURE register must be enabled. In RX mode the DYNPD register must be set. A PTX that transmits to a PRX with DPL enabled must have the DPL_P0 bit in DYNPD set. 7.3.5 CRC (Cyclic Redundancy Check) The CRC is the mandatory error detection mechanism in the packet. It is either 1 or 2 bytes and is calculated over the address, Packet Control Field and Payload. The polynomial for 1 byte CRC is X8 + X2 + X + 1. Initial value 0xFF. The polynomial for 2 byte CRC is X16+ X12 + X5 + 1. Initial value 0xFFFF. The number of bytes in the CRC is set by the CRCO bit in the CONFIG register. No packet is accepted by Enhanced ShockBurst™ if the CRC fails. Revision 1.0 Page 30 of 78 nRF24L01+ Product Specification 7.3.6 Automatic packet assembly The automatic packet assembly assembles the preamble, address, packet control field, payload and CRC to make a complete packet before it is transmitted. Start: Collect Address from TX_ADDR register TX_ADDR MSB =1 Add preamble 0x55 Add preamble 0xAA EN_DPL=1 PID[7:3]= #bytes in TX_FIFO New data in TX_FIFO REUSE_TX_PL active PID[2:1]++ SPI TX command: W_TX_PAYLOAD PID[0]=0 PID[0]=1 Collect Payload from TX_FIFO EN_CRC = 1 CRCO = 1 Calculate and add 2 Byte CRC based on Address, PID and Payload Calculate and add 1 Byte CRC based on Address, PID and Payload STOP Figure 7. Automatic packet assembly Revision 1.0 Page 31 of 78 nRF24L01+ Product Specification 7.3.7 Automatic packet disassembly After the packet is validated, Enhanced ShockBurst™ disassembles the packet and loads the payload into the RX FIFO, and asserts the RX_DR IRQ. Start Read Address width from SETUP_AW Monitor SETUP_AW wide window of received bit stream Received window = RX_ADDR_Px PID = 1 byte from received bit stream EN_DPL=1 Payload = PID[7:3] bytes from received bit stream Payload = RX_PW_Px bytes from received bit stream CRCO = 1 TX_CRC = 2 Bytes from received bit stream TX_CRC = 1 Byte from received bit stream RX_CRC = 2 Byte CRC calculated from received Address, PID and Payload RX_CRC = 1 Byte CRC calculated from received Address, PID and Payload TX_CRC = RX_CRC PID[2:1] Changed from last packet CRC Changed from last packet New packet received Duplicate received STOP Figure 8. Automatic packet disassembly Revision 1.0 Page 32 of 78 nRF24L01+ Product Specification 7.4 Automatic packet transaction handling Enhanced ShockBurst™ has two functions for automatic packet transaction handling; auto acknowledgement and auto re-transmit. 7.4.1 Auto acknowledgement Auto acknowledgment is a function that automatically transmits an ACK packet to the PTX after it has received and validated a packet. The auto acknowledgement function reduces the load of the system MCU and can remove the need for dedicated SPI hardware. This also reduces cost and average current consumption. The Auto Acknowledgement feature is enabled by setting the EN_AA register. Note: If the received packet has the NO_ACK flag set, auto acknowledgement is not executed. An ACK packet can contain an optional payload from PRX to PTX. In order to use this feature, the Dynamic Payload Length (DPL) feature must be enabled. The MCU on the PRX side has to upload the payload by clocking it into the TX FIFO by using the W_ACK_PAYLOAD command. The payload is pending in the TX FIFO (PRX) until a new packet is received from the PTX. nRF24L01+ can have three ACK packet payloads pending in the TX FIFO (PRX) at the same time. RX Pipe address ACK generator Address decoder and buffer controller TX FIFO Payload 3 Payload 2 Payload 1 TX Pipe address SPI Module From MCU Figure 9. TX FIFO (PRX) with pending payloads Figure 9. shows how the TX FIFO (PRX) is operated when handling pending ACK packet payloads. From the MCU the payload is clocked in with the W_ACK_PAYLOAD command. The address decoder and buffer controller ensure that the payload is stored in a vacant slot in the TX FIFO (PRX). When a packet is received, the address decoder and buffer controller are notified with the PTX address. This ensures that the right payload is presented to the ACK generator. If the TX FIFO (PRX) contains more than one payload to a PTX, payloads are handled using the first in – first out principle. The TX FIFO (PRX) is blocked if all pending payloads are addressed to a PTX where the link is lost. In this case, the MCU can flush the TX FIFO (PRX) by using the FLUSH_TX command. In order to enable Auto Acknowledgement with payload the EN_ACK_PAY bit in the FEATURE register must be set. 7.4.2 Auto Retransmission (ART) The auto retransmission is a function that retransmits a packet if an ACK packet is not received. It is used in an auto acknowledgement system on the PTX. When a packet is not acknowledged, you can set the number of times it is allowed to retransmit by setting the ARC bits in the SETUP_RETR register. PTX enters RX mode and waits a short period for an ACK packet each time a packet is transmitted. The time period the PTX is in RX mode is based on the following conditions: Revision 1.0 Page 33 of 78 nRF24L01+ Product Specification • • • Auto Retransmit Delay (ARD) has elapsed. No address match within 250µs (or 500µs in 250kbps mode). After received packet (CRC correct or not). nRF24L01+ asserts the TX_DS IRQ when the ACK packet is received. nRF24L01+ enters standby-I mode if there is no more untransmitted data in the TX FIFO and the CE pin is low. If the ACK packet is not received, nRF24L01+ goes back to TX mode after a delay defined by ARD and retransmits the data. This continues until acknowledgment is received, or the maximum number of retransmits is reached. Two packet loss counters are incremented each time a packet is lost, ARC_CNT and PLOS_CNT in the OBSERVE_TX register. The ARC_CNT counts the number of retransmissions for the current transaction. You reset ARC_CNT by initiating a new transaction. The PLOS_CNT counts the total number of retransmissions since the last channel change. You reset PLOS_CNT by writing to the RF_CH register. It is possible to use the information in the OBSERVE_TX register to make an overall assessment of the channel quality. The ARD defines the time from the end of a transmitted packet to when a retransmit starts on the PTX. ARD is set in SETUP_RETR register in steps of 250µs. A retransmit is made if no ACK packet is received by the PTX. There is a restriction on the length of ARD when using ACK packets with payload. The ARD time must never be shorter than the sum of the startup time and the time on-air for the ACK packet: • • For 2Mbps data rate and 5 byte address; 15 byte is maximum ACK packet payload length for ARD=250µs (reset value). For 1Mbps data rate and 5 byte address; 5 byte is maximum ACK packet payload length for ARD=250µs (reset value). ARD=500µs is long enough for any ACK payload length in 1 or 2Mbps mode. • For 250kbps data rate and 5byte address the following values apply: ARD 1500µs 1250µs 1000µs 750µs 500µs ACK packet size (in bytes) All ACK payload sizes < 24 < 16 10us TIRQ TUL PTX SPI Tstdby2a TOA IRQ: TX DS1 UL PTX CE PTX IRQ PTX MODE Standby-I PLL Lock TX Standby-I 1 IRQ if No Ack is on. TIRQ = 8.2µs @ 1Mbps, TIRQ = 6.0µs @ 2Mbps, Tstdby2a = 130us Figure 15. Transmitting one packet with NO_ACK on The following equations calculate various timing measurements: Symbol TOA Description Time on-air Equation ⎤ ⋅ ⎛⎜1[byte]+ 3,4 or 5 [bytes ]+ N [bytes ]+ 1 or 2 [bytes ]⎞⎟ + 8⎡bit ⎣⎢ byte ⎥⎦ ⎝ preamble packet length address payload CRC ⎠ = = air data rate air data rate bit s packet control field T ACK = ⎤ ⋅ ⎛⎜1 [byte]+ 3,4 or 5 [bytes]+ N [bytes ]+ 1 or 2 [bytes ]⎞⎟ + 8⎡bit ⎣⎢ byte⎥⎦ ⎝ preamble packet length address payload CRC ⎠ = air data rate air data rate bit s packet control field TU L = ⎤ ⋅ N [bytes ] 8 ⎡ bit payload length ⎣⎢ byte ⎥⎦ payload = SPI data rate SPI data rate bit s TOA Time on-air Ack TACK [ ] Time Upload TUL TESB [ ] 9 [bit ] [ ] Time Enhanced Shock- TESB = TUL + 2 . Tstby2a + TOA + TACK + TIRQ Burst™ cycle Table 19. Timing equations Revision 1.0 Page 42 of 78 9 [bit ] nRF24L01+ Product Specification TESB Cycle >10us TUL PTX SPI 130us TIRQ TOA IRQ: TX DS UL PTX CE PTX IRQ PTX MODE PRX MODE Standby 1 Standby 1 PLL Lock PLL Lock TX RX PLL Lock RX Standby 1 PLL Lock TX PLL Lock TACK 130us RX PRX IRQ PRX CE PRX SPI IRQ:RX DR/DL 130us 130us TIRQ Figure 16. Timing of Enhanced ShockBurst™ for one packet upload (2Mbps) In Figure 16. the transmission and acknowledgement of a packet is shown. The PRX device activates RX mode (CE=1), and the PTX device is activated in TX mode (CE=1 for minimum 10µs). After 130µs the transmission starts and finishes after the elapse of TOA. When the transmission ends the PTX device automatically switches to RX mode to wait for the ACK packet from the PRX device. When the PRX device receives the packet it sets the interrupt for the host MCU and switches to TX mode to send an ACK. After the PTX device receives the ACK packet it sets the interrupt to the MCU and clears the packet from the TX FIFO. Revision 1.0 Page 43 of 78 nRF24L01+ Product Specification In Figure 17. the PTX timing of a packet transmission is shown when the first ACK packet is lost. To see the complete transmission when the ACK packet fails see Figure 20. on page 46. >10us TUL PTX SPI ARD 130us TOA 130us PLL Lock TX PLL Lock 250us max 130us UL PTX CE PTX IRQ PTX MODE Standby I RX Standby II PLL Lock TX Figure 17. Timing of Enhanced ShockBurst™ when the first ACK packet is lost (2Mbps) Revision 1.0 Page 44 of 78 nRF24L01+ Product Specification 7.8 Enhanced ShockBurst™ transaction diagram This section describes several scenarios for the Enhanced ShockBurst™ automatic transaction handling. The call outs in this section’s figures indicate the IRQs and other events. For MCU activity the event may be placed at a different timeframe. Note: The figures in this section indicate the earliest possible download (DL) of the packet to the MCU and the latest possible upload (UL) of payload to the transmitter. 7.8.1 Single transaction with ACK packet and interrupts In Figure 18. the basic auto acknowledgement is shown. After the packet is transmitted by the PTX and received by the PRX the ACK packet is transmitted from the PRX to the PTX. The RX_DR IRQ is asserted after the packet is received by the PRX, whereas the TX_DS IRQ is asserted when the packet is acknowledged and the ACK packet is received by the PTX. MCU PTX UL IRQ Ack received IRQ:TX DS (PID=1) 130us1 PTX TX:PID=1 RX PRX RX ACK:PID=1 Packet received IRQ: RX DR (PID=1) MCU PRX DL 1 Radio Turn Around Delay Figure 18. TX/RX cycles with ACK and the according interrupts Revision 1.0 Page 45 of 78 nRF24L01+ Product Specification 7.8.2 Single transaction with a lost packet Figure 19. is a scenario where a retransmission is needed due to loss of the first packet transmit. After the packet is transmitted, the PTX enters RX mode to receive the ACK packet. After the first transmission, the PTX waits a specified time for the ACK packet, if it is not in the specific time slot the PTX retransmits the packet as shown in Figure 19. MCU PTX UL IRQ Packet PID=1 lost during transmission No address detected. RX off to save current Auto retransmit delay elapsed 130us1 PTX TX:PID=1 Retransmit of packet PID=1 130us1 ACK received IRQ: TX DS (PID=1) 130us1 RX TX:PID=1 RX ARD PRX RX ACK:PID=1 Packet received. IRQ: RX DR (PID=1) MCU PRX DL 1 Radio Turn Around Delay Figure 19. TX/RX cycles with ACK and the according interrupts when the first packet transmit fails When an address is detected the PTX stays in RX mode until the packet is received. When the retransmitted packet is received by the PRX (see Figure 19.), the RX_DR IRQ is asserted and an ACK is transmitted back to the PTX. When the ACK is received by the PTX, the TX_DS IRQ is asserted. 7.8.3 Single transaction with a lost ACK packet Figure 20. is a scenario where a retransmission is needed after a loss of the ACK packet. The corresponding interrupts are also indicated. MCU PTX UL IRQ No address detected. RX off to save current 130us PTX TX:PID=1 Auto retransmit delay elapsed 1 130us Retransmit of packet PID=1 1 RX ACK received IRQ: TX DS (PID=1) 130us1 TX:PID=1 RX ARD PRX RX ACK:PID=1 Packet received. IRQ: RX DR (PID=1) MCU PRX ACK PID=1 lost during transmission RX ACK:PID=1 Packet detected as copy of previous, discarded DL 1 Radio Turn Around Delay Figure 20. TX/RX cycles with ACK and the according interrupts when the ACK packet fails Revision 1.0 Page 46 of 78 nRF24L01+ Product Specification 7.8.4 Single transaction with ACK payload packet Figure 21. is a scenario of the basic auto acknowledgement with payload. After the packet is transmitted by the PTX and received by the PRX the ACK packet with payload is transmitted from the PRX to the PTX. The RX_DR IRQ is asserted after the packet is received by the PRX, whereas on the PTX side the TX_DS IRQ is asserted when the ACK packet is received by the PTX. On the PRX side, the TX_DS IRQ for the ACK packet payload is asserted after a new packet from PTX is received. The position of the IRQ in Figure 21. shows where the MCU can respond to the interrupt. MCU PTX UL1 DL IRQ UL2 ACK received IRQ: TX DS (PID=1) RX DR (ACK1PAY) Transmit of packet PID=2 ≥130us3 130us1 PTX TX:PID=1 PRX RX RX TX:PID=2 ACK1 PAY RX Packet received. IRQ: RX DR (PID=2) TX DS (ACK1PAY) Packet received. IRQ: RX DR (PID=1) MCU PRX UL2 DL IRQ DL 1 Radio Turn Around Delay 2 Uploading Payload for Ack Packet 3 Delay defined by MCU on PTX side, ≥ 130us Figure 21. TX/RX cycles with ACK Payload and the according interrupts 7.8.5 Single transaction with ACK payload packet and lost packet Figure 22. is a scenario where the first packet is lost and a retransmission is needed before the RX_DR IRQ on the PRX side is asserted. For the PTX both the TX_DS and RX_DR IRQ are asserted after the ACK packet is received. After the second packet (PID=2) is received on the PRX side both the RX_DR (PID=2) and TX_DS (ACK packet payload) IRQ are asserted. MCU PTX UL1 DL IRQ UL2 Packet PID=1 lost during transmission No address detected. RX off to save current Auto retransmit delay elapsed 130us1 PTX TX:PID=1 Retransmit of packet PID=1 130us1 RX ACK received IRQ: TX DS (PID=1) RX DR (ACK1PAY) ≥130us3 130us1 TX:PID=1 RX TX:PID=2 ACK1 PAY RX ARD PRX RX Packet received. IRQ: RX DR (PID=2) TX DS (ACK1PAY) Packet received. IRQ: RX DR (PID=1) MCU PRX UL 2 DL DL 1 Radio Turn Around Delay 2 Uploading Paylod for Ack Packet 3 Delay defined by MCU on PTX side, ≥ 130us Figure 22. TX/RX cycles and the according interrupts when the packet transmission fails Revision 1.0 Page 47 of 78 nRF24L01+ Product Specification 7.8.6 Two transactions with ACK payload packet and the first ACK packet lost MCU PTX UL1 UL2 130us PTX TX:PID=1 DL IRQ UL3 No address detected. RX off to save current Auto retransmit delay elapsed 1 130us ACK received IRQ: TX DS (PID=1) RX DR (ACK1PAY) Retransmit of packet PID=1 1 RX 130us TX:PID=1 ACK received IRQ: TX DS (PID=2) RX DR (ACK2PAY) ≥ 130us3 1 ≥130us3 130us 1 RX TX:PID=2 RX TX:PID=3 ACK1 PAY RX ACK2 PAY RX ARD PRX RX ACK1 PAY Packet received. IRQ: RX DR (PID=1) MCU PRX UL1 2 RX Packet detected as copy of previous, discarded ACK PID=1 lost during transmission DL UL2 Packet received. IRQ: RX DR (PID=2) TX DS (ACK1PAY) Packet received. IRQ: RX DR (PID=3) TX DS (ACK2PAY) DL IRQ 2 1 Radio Turn Around Delay 2 Uploading Payload for Ack Packet 3 Delay defined by MCU on PTX side, ≥ 130us Figure 23. TX/RX cycles with ACK Payload and the according interrupts when the ACK packet fails In Figure 23. the ACK packet is lost and a retransmission is needed before the TX_DS IRQ is asserted, but the RX_DR IRQ is asserted immediately. The retransmission of the packet (PID=1) results in a discarded packet. For the PTX both the TX_DS and RX_DR IRQ are asserted after the second transmission of ACK, which is received. After the second packet (PID=2) is received on the PRX both the RX_DR (PID=2) and TX_DS (ACK1PAY) IRQ is asserted. The callouts explains the different events and interrupts. 7.8.7 Two transactions where max retransmissions is reached MCU PTX UL IRQ No address detected. RX off to save current Auto retransmit delay elapsed 130us1 PTX TX:PID=1 Retransmit of packet PID=1 130us1 RX ≥130us3 130us1 TX:PID=1 No address detected. RX off to save current RX ARD No address detected. RX off to save current. IRQ:MAX_RT reached 130us1 TX:PID=1 RX ARD 130us1 PRX RX ACK1 PAY Packet received. IRQ: RX DR (PID=1) MCU PRX UL2 RX ACK PID=1 lost during transmission ACK PID=1 lost during transmission ACK1 PAY Packet detected as copy of previous, discarded RX ACK PID=1 lost during transmission DL 1 Radio Turn Around Delay 2 Uploading Paylod for Ack Packet 3 Delay defined by MCU on PTX side, ≥ 130us Figure 24. TX/RX cycles with ACK Payload and the according interrupts when the transmission fails. ARC is set to 2. MAX_RT IRQ is asserted if the auto retransmit counter (ARC_CNT) exceeds the programmed maximum limit (ARC). In Figure 24. the packet transmission ends with a MAX_RT IRQ. The payload in TX FIFO is NOT removed and the MCU decides the next step in the protocol. A toggle of the CE starts a new transmitting sequence of the same packet. The payload can be removed from the TX FIFO using the FLUSH_TX command. Revision 1.0 Page 48 of 78 nRF24L01+ Product Specification 7.9 Compatibility with ShockBurst™ You must disable Enhanced ShockBurst™ for backward compatibility with the nRF2401A, nRF2402, nRF24E1 and nRF24E2. Set the register EN_AA = 0x00 and ARC = 0 to disable Enhanced ShockBurst™. In addition, the nRF24L01+ air data rate must be set to 1Mbps or 250kbps. 7.9.1 ShockBurst™ packet format Figure 25. shows the packet format with MSB to the left. Preamble 1 byte Address 3-5 byte Payload 1 - 32 byte CRC 1-2 byte Figure 25. A ShockBurst™ packet compatible with nRF2401/nRF2402/nRF24E1/nRF24E2 devices. The ShockBurst™ packet format has a preamble, address, payload and CRC field that are the same as the Enhanced ShockBurst™ packet format described in section 7.3 on page 28. The differences between the ShockBurst™ packet and the Enhanced ShockBurst™ packet are: • • The 9 bit Packet Control Field is not present in the ShockBurst™ packet format. The CRC is optional in the ShockBurst™ packet format and is controlled by the EN_CRC bit in the CONFIG register. Revision 1.0 Page 49 of 78 nRF24L01+ Product Specification 8 Data and Control Interface The data and control interface gives you access to all the features in the nRF24L01+. The data and control interface consists of the following six 5Volt tolerant digital signals: • • • • • • IRQ (this signal is active low and controlled by three maskable interrupt sources) CE (this signal is active high and used to activate the chip in RX or TX mode) CSN (SPI signal) SCK (SPI signal) MOSI (SPI signal) MISO (SPI signal) Using 1 byte SPI commands, you can activate the nRF24L01+ data FIFOs or the register map during all modes of operation. 8.1 • • • • • 8.2 Features Special SPI commands for quick access to the most frequently used features 0-10Mbps 4-wire SPI 8 bit command set Easily configurable register map Full three level FIFO for both TX and RX direction Functional description The SPI is a standard SPI with a maximum data rate of 10Mbps. 8.3 SPI operation This section describes the SPI commands and timing. 8.3.1 SPI commands The SPI commands are shown in Table 20. Every new command must be started by a high to low transition on CSN. The STATUS register is serially shifted out on the MISO pin simultaneously to the SPI command word shifting to the MOSI pin. The serial shifting SPI commands is in the following format: See Figure 26. on page 52 and Figure 27. on page 52 for timing information. Revision 1.0 Page 50 of 78 nRF24L01+ Product Specification Command name R_REGISTER W_REGISTER Command # Data bytes word (binary) 000A AAAA 1 to 5 LSByte first 001A AAAA 1 to 5 LSByte first R_RX_PAYLOAD 0110 0001 1 to 32 LSByte first W_TX_PAYLOAD 1010 0000 FLUSH_TX FLUSH_RX 1110 0001 1110 0010 1 to 32 LSByte first 0 0 REUSE_TX_PL 1110 0011 0 R_RX_PL_WIDa 0110 0000 1 W_ACK_PAYLOADa 1010 1PPP 1 to 32 LSByte first W_TX_PAYLOAD_NO ACKa NOP 1011 0000 1 to 32 LSByte first 0 1111 1111 Operation Read command and status registers. AAAAA = 5 bit Register Map Address Write command and status registers. AAAAA = 5 bit Register Map Address Executable in power down or standby modes only. Read RX-payload: 1 – 32 bytes. A read operation always starts at byte 0. Payload is deleted from FIFO after it is read. Used in RX mode. Write TX-payload: 1 – 32 bytes. A write operation always starts at byte 0 used in TX payload. Flush TX FIFO, used in TX mode Flush RX FIFO, used in RX mode Should not be executed during transmission of acknowledge, that is, acknowledge package will not be completed. Used for a PTX device Reuse last transmitted payload. TX payload reuse is active until W_TX_PAYLOAD or FLUSH TX is executed. TX payload reuse must not be activated or deactivated during package transmission. Read RX payload width for the top R_RX_PAYLOAD in the RX FIFO. Note: Flush RX FIFO if the read value is larger than 32 bytes. Used in RX mode. Write Payload to be transmitted together with ACK packet on PIPE PPP. (PPP valid in the range from 000 to 101). Maximum three ACK packet payloads can be pending. Payloads with same PPP are handled using first in - first out principle. Write payload: 1– 32 bytes. A write operation always starts at byte 0. Used in TX mode. Disables AUTOACK on this specific packet. No Operation. Might be used to read the STATUS register a. The bits in the FEATURE register shown in Table 28. on page 63 have to be set. Table 20. Command set for the nRF24L01+ SPI The W_REGISTER and R_REGISTER commands operate on single or multi-byte registers. When accessing multi-byte registers read or write to the MSBit of LSByte first. You can terminate the writing before all bytes in a multi-byte register are written, leaving the unwritten MSByte(s) unchanged. For example, the LSByte of RX_ADDR_P0 can be modified by writing only one byte to the RX_ADDR_P0 register. The content of the status register is always read to MISO after a high to low transition on CSN. Revision 1.0 Page 51 of 78 nRF24L01+ Product Specification Note: The 3 bit pipe information in the STATUS register is updated during the IRQ pin high to low transition. The pipe information is unreliable if the STATUS register is read during an IRQ pin high to low transition. 8.3.2 SPI timing SPI operation and timing is shown in Figure 26. to Figure 28. and in Table 22. to Table 27.. nRF24L01+ must be in a standby or power down mode before writing to the configuration registers. In Figure 26. to Figure 28. the following abbreviations are used: Abbreviation Description Cn SPI command bit STATUS register bit Sn Dn Data Bit (Note: LSByte to MSByte, MSBit in each byte first) Table 21. Abbreviations used in Figure 26. to Figure 28. CSN SCK MOSI C7 C6 C5 C4 C3 C2 C1 C0 MISO S7 S6 S5 S4 S3 S2 S1 S0 D7 D6 D5 D4 D3 D2 D1 D0 D1 5 D1 4 D1 3 D1 2 D1 1 D1 0 D9 D9 D8 Figure 26. SPI read operation CSN SCK MOSI C7 C6 C5 C4 C3 C2 C1 C0 MISO S7 S6 S5 S4 S3 S2 S1 S0 D7 D6 D5 D4 D3 D2 D1 D0 D1 5 D1 4 D1 3 Figure 27. SPI write operation Tcwh CSN Tcc Tch Tcl Tcch SCK Tdh Tdc MOSI C7 C6 Tcsd MISO C0 Tcd S7 Tcdz S0 Figure 28. SPI NOP timing diagram Revision 1.0 Page 52 of 78 D1 2 D1 1 D1 0 D8 nRF24L01+ Product Specification Figure 29. shows the Rpull and Cload that are referenced in Table 22. to Table 27. Vdd Rpull External nRF24L01+ pin Cload Figure 29. Rpull and Cload Symbol Tdc Tdh Tcsd Tcd Tcl Tch Fsck Tr,Tf Tcc Tcch Tcwh Tcdz Parameters Data to SCK Setup SCK to Data Hold CSN to Data Valid SCK to Data Valid SCK Low Time SCK High Time SCK Frequency SCK Rise and Fall CSN to SCK Setup SCK to CSN Hold CSN Inactive time CSN to Output High Z Min. 2 2 Max 38 55 40 40 0 10 100 2 2 50 38 Units ns ns ns ns ns ns MHz ns ns ns ns ns Table 22. SPI timing parameters (Cload = 5pF) Symbol Tdc Tdh Tcsd Tcd Tcl Tch Fsck Tr,Tf Tcc Revision 1.0 Parameters Data to SCK Setup SCK to Data Hold CSN to Data Valid SCK to Data Valid SCK Low Time SCK High Time SCK Frequency SCK Rise and Fall CSN to SCK Setup Min. 2 2 Max 42 58 40 40 0 2 Page 53 of 78 8 100 Units ns ns ns ns ns ns MHz ns ns nRF24L01+ Product Specification Symbol Tcch Tcwh Tcdz Parameters SCK to CSN Hold CSN Inactive time CSN to Output High Z Min. 2 50 Max 42 Units ns ns ns Table 23. SPI timing parameters (Cload = 10pF) Symbol Tdc Tdh Tcsd Tcd Tcl Tch Fsck Tr,Tf Tcc Tcch Tcwh Tcdz Parameters Data to SCK Setup SCK to Data Hold CSN to Data Valid SCK to Data Valid SCK Low Time SCK High Time SCK Frequency SCK Rise and Fall CSN to SCK Setup SCK to CSN Hold CSN Inactive time CSN to Output High Z Min. 2 2 Max 75 86 40 40 0 5 100 2 2 50 75 Units ns ns ns ns ns ns MHz ns ns ns ns ns Table 24. SPI timing parameters (Rpull = 10kΩ, Cload = 50pF) Symbol Tdc Tdh Tcsd Tcd Tcl Tch Fsck Tr,Tf Tcc Tcch Tcwh Tcdz Parameters Data to SCK Setup SCK to Data Hold CSN to Data Valid SCK to Data Valid SCK Low Time SCK High Time SCK Frequency SCK Rise and Fall CSN to SCK Setup SCK to CSN Hold CSN Inactive time CSN to Output High Z Min. 2 2 Max 116 123 40 40 0 4 100 2 2 50 116 Table 25. SPI timing parameters (Rpull = 10kΩ, Cload = 100pF) Revision 1.0 Page 54 of 78 Units ns ns ns ns ns ns MHz ns ns ns ns ns nRF24L01+ Product Specification Symbol Tdc Tdh Tcsd Tcd Tcl Tch Fsck Tr,Tf Tcc Tcch Tcwh Tcdz Parameters Data to SCK Setup SCK to Data Hold CSN to Data Valid SCK to Data Valid SCK Low Time SCK High Time SCK Frequency SCK Rise and Fall CSN to SCK Setup SCK to CSN Hold CSN Inactive time CSN to Output High Z Min. 2 2 Max 75 85 40 40 0 5 100 2 2 50 75 Units ns ns ns ns ns ns MHz ns ns ns ns ns Table 26. SPI timing parameters (Rpull = 50kΩ, Cload = 50pF) Symbol Tdc Tdh Tcsd Tcd Tcl Tch Fsck Tr,Tf Tcc Tcch Tcwh Tcdz Parameters Data to SCK Setup SCK to Data Hold CSN to Data Valid SCK to Data Valid SCK Low Time SCK High Time SCK Frequency SCK Rise and Fall CSN to SCK Setup SCK to CSN Hold CSN Inactive time CSN to Output High Z Min. 2 2 Max 116 121 40 40 0 4 100 2 2 50 116 Units ns ns ns ns ns ns MHz ns ns ns ns ns Table 27. SPI timing parameters (Rpull = 50kΩ, Cload = 100pF) 8.4 Data FIFO The data FIFOs store transmitted payloads (TX FIFO) or received payloads that are ready to be clocked out (RX FIFO). The FIFOs are accessible in both PTX mode and PRX mode. The following FIFOs are present in nRF24L01+: • • TX three level, 32 byte FIFO RX three level, 32 byte FIFO Both FIFOs have a controller and are accessible through the SPI by using dedicated SPI commands. A TX FIFO in PRX can store payloads for ACK packets to three different PTX devices. If the TX FIFO contains more than one payload to a pipe, payloads are handled using the first in - first out principle. The TX FIFO in a PRX is blocked if all pending payloads are addressed to pipes where the link to the PTX is lost. In this case, the MCU can flush the TX FIFO using the FLUSH_TX command. The RX FIFO in PRX can contain payloads from up to three different PTX devices and a TX FIFO in PTX can have up to three payloads stored. Revision 1.0 Page 55 of 78 nRF24L01+ Product Specification You can write to the TX FIFO using these three commands; W_TX_PAYLOAD and W_TX_PAYLOAD_NO_ACK in PTX mode and W_ACK_PAYLOAD in PRX mode. All three commands provide access to the TX_PLD register (see Table 28. on page 63. for details of this register). The RX FIFO can be read by the command R_RX_PAYLOAD in PTX and PRX mode. This command provides access to the RX_PLD register. The payload in TX FIFO in a PTX is not removed if the MAX_RT IRQ is asserted. RX FIFO 32 byte 32 byte 32 byte RX FIFO Controller TX FIFO Controller Data Control SPI command decoder SPI Data Control TX FIFO Data 32 byte 32 byte Data 32 byte Figure 30. FIFO (RX and TX) block diagram You can read if the TX and RX FIFO are full or empty in the FIFO_STATUS register. 8.5 Interrupt The nRF24L01+ has an active low interrupt (IRQ) pin. The IRQ pin is activated when TX_DS IRQ, RX_DR IRQ or MAX_RT IRQ are set high by the state machine in the STATUS register. The IRQ pin resets when MCU writes '1' to the IRQ source bit in the STATUS register. The IRQ mask in the CONFIG register is used to select the IRQ sources that are allowed to assert the IRQ pin. By setting one of the MASK bits high, the corresponding IRQ source is disabled. By default all IRQ sources are enabled. Note: The 3 bit pipe information in the STATUS register is updated during the IRQ pin high to low transition. The pipe information is unreliable if the STATUS register is read during an IRQ pin high to low transition. Revision 1.0 Page 56 of 78 nRF24L01+ Product Specification 9 Register Map You can configure and control the radio by accessing the register map through the SPI. 9.1 Register map table All undefined bits in the table below are redundant. They are read out as '0'. Note: Addresses 18 to 1B are reserved for test purposes, altering them makes the chip malfunction. Address (Hex) 00 01 Mnemonic Bit Reset Value CONFIG Reserved MASK_RX_DR 7 6 0 0 MASK_TX_DS 5 0 MASK_MAX_RT 4 0 EN_CRC 3 1 CRCO 2 0 PWR_UP PRIM_RX 1 0 0 0 Type Description Configuration Register R/W Only '0' allowed R/W Mask interrupt caused by RX_DR 1: Interrupt not reflected on the IRQ pin 0: Reflect RX_DR as active low interrupt on the IRQ pin R/W Mask interrupt caused by TX_DS 1: Interrupt not reflected on the IRQ pin 0: Reflect TX_DS as active low interrupt on the IRQ pin R/W Mask interrupt caused by MAX_RT 1: Interrupt not reflected on the IRQ pin 0: Reflect MAX_RT as active low interrupt on the IRQ pin R/W Enable CRC. Forced high if one of the bits in the EN_AA is high R/W CRC encoding scheme '0' - 1 byte '1' – 2 bytes R/W 1: POWER UP, 0:POWER DOWN R/W RX/TX control 1: PRX, 0: PTX EN_AA Enhanced ShockBurst™ Reserved ENAA_P5 ENAA_P4 ENAA_P3 ENAA_P2 ENAA_P1 ENAA_P0 7:6 5 4 3 2 1 0 00 1 1 1 1 1 1 R/W R/W R/W R/W R/W R/W R/W Enable ‘Auto Acknowledgment’ Function Disable this functionality to be compatible with nRF2401, see page 75 Only '00' allowed Enable auto acknowledgement data pipe 5 Enable auto acknowledgement data pipe 4 Enable auto acknowledgement data pipe 3 Enable auto acknowledgement data pipe 2 Enable auto acknowledgement data pipe 1 Enable auto acknowledgement data pipe 0 EN_RXADDR Reserved ERX_P5 ERX_P4 ERX_P3 ERX_P2 7:6 5 4 3 2 00 0 0 0 0 R/W R/W R/W R/W R/W Enabled RX Addresses Only '00' allowed Enable data pipe 5. Enable data pipe 4. Enable data pipe 3. Enable data pipe 2. 02 Revision 1.0 Page 57 of 78 nRF24L01+ Product Specification Address (Hex) 03 04 Mnemonic Bit ERX_P1 ERX_P0 1 0 Reset Value 1 1 SETUP_AW Reserved AW 7:2 1:0 000000 11 SETUP_RETR ARDa 7:4 0000 ARC 3:0 0011 RF_CH Reserved RF_CH 7 6:0 0 0000010 RF_SETUP CONT_WAVE Reserved RF_DR_LOW 7 6 5 0 0 0 PLL_LOCK RF_DR_HIGH 4 3 0 1 05 06 Revision 1.0 Type Description R/W Enable data pipe 1. R/W Enable data pipe 0. Setup of Address Widths (common for all data pipes) R/W Only '000000' allowed R/W RX/TX Address field width '00' - Illegal '01' - 3 bytes '10' - 4 bytes '11' – 5 bytes LSByte is used if address width is below 5 bytes Setup of Automatic Retransmission R/W Auto Retransmit Delay ‘0000’ – Wait 250µS ‘0001’ – Wait 500µS ‘0010’ – Wait 750µS …….. ‘1111’ – Wait 4000µS (Delay defined from end of transmission to start of next transmission)b R/W Auto Retransmit Count ‘0000’ –Re-Transmit disabled ‘0001’ – Up to 1 Re-Transmit on fail of AA …… ‘1111’ – Up to 15 Re-Transmit on fail of AA RF Channel R/W Only '0' allowed R/W Sets the frequency channel nRF24L01+ operates on RF Setup Register R/W Enables continuous carrier transmit when high. R/W Only '0' allowed R/W Set RF Data Rate to 250kbps. See RF_DR_HIGH for encoding. R/W Force PLL lock signal. Only used in test R/W Select between the high speed data rates. This bit is don’t care if RF_DR_LOW is set. Encoding: [RF_DR_LOW, RF_DR_HIGH]: ‘00’ – 1Mbps ‘01’ – 2Mbps ‘10’ – 250kbps ‘11’ – Reserved Page 58 of 78 nRF24L01+ Product Specification Address (Hex) 07 08 Bit RF_PWR 2:1 Obsolete 0 Reset Value 11 Type Reserved RX_DR 7 6 0 0 R/W R/W TX_DS 5 0 R/W MAX_RT 4 0 R/W RX_P_NO 3:1 111 R TX_FULL 0 0 R OBSERVE_TX PLOS_CNT 7:4 0 R ARC_CNT 3:0 0 R RPD Reserved RPD 7:1 0 000000 0 R R RX_ADDR_P0 39:0 0xE7E7E 7E7E7 Revision 1.0 Description R/W Set RF output power in TX mode '00' – -18dBm '01' – -12dBm '10' – -6dBm '11' – 0dBm Don’t care STATUS 09 0A Mnemonic Status Register (In parallel to the SPI command word applied on the MOSI pin, the STATUS register is shifted serially out on the MISO pin) Only '0' allowed Data Ready RX FIFO interrupt. Asserted when new data arrives RX FIFOc. Write 1 to clear bit. Data Sent TX FIFO interrupt. Asserted when packet transmitted on TX. If AUTO_ACK is activated, this bit is set high only when ACK is received. Write 1 to clear bit. Maximum number of TX retransmits interrupt Write 1 to clear bit. If MAX_RT is asserted it must be cleared to enable further communication. Data pipe number for the payload available for reading from RX_FIFO 000-101: Data Pipe Number 110: Not Used 111: RX FIFO Empty TX FIFO full flag. 1: TX FIFO full. 0: Available locations in TX FIFO. Transmit observe register Count lost packets. The counter is overflow protected to 15, and discontinues at max until reset. The counter is reset by writing to RF_CH. See page 75. Count retransmitted packets. The counter is reset when transmission of a new packet starts. See page 75. Received Power Detector. This register is called CD (Carrier Detect) in the nRF24L01. The name is different in nRF24L01+ due to the different input power level threshold for this bit. See section 6.4 on page 25. R/W Receive address data pipe 0. 5 Bytes maximum length. (LSByte is written first. Write the number of bytes defined by SETUP_AW) Page 59 of 78 nRF24L01+ Product Specification Address (Hex) 0B Mnemonic Bit RX_ADDR_P1 39:0 0C RX_ADDR_P2 7:0 0D RX_ADDR_P3 7:0 0E RX_ADDR_P4 7:0 0F RX_ADDR_P5 7:0 10 TX_ADDR 39:0 0xE7E7E 7E7E7 R/W Transmit address. Used for a PTX device only. (LSByte is written first) Set RX_ADDR_P0 equal to this address to handle automatic acknowledge if this is a PTX device with Enhanced ShockBurst™ enabled. See page 75. 11 RX_PW_P0 Reserved RX_PW_P0 7:6 5:0 00 0 R/W Only '00' allowed R/W Number of bytes in RX payload in data pipe 0 (1 to 32 bytes). 0 Pipe not used 1 = 1 byte … 32 = 32 bytes RX_PW_P1 Reserved RX_PW_P1 7:6 5:0 00 0 R/W Only '00' allowed R/W Number of bytes in RX payload in data pipe 1 (1 to 32 bytes). 0 Pipe not used 1 = 1 byte … 32 = 32 bytes RX_PW_P2 Reserved RX_PW_P2 7:6 5:0 00 0 R/W Only '00' allowed R/W Number of bytes in RX payload in data pipe 2 (1 to 32 bytes). 0 Pipe not used 1 = 1 byte … 32 = 32 bytes RX_PW_P3 Reserved 7:6 00 R/W Only '00' allowed 12 13 14 Revision 1.0 Reset Type Description Value 0xC2C2C R/W Receive address data pipe 1. 5 Bytes maximum 2C2C2 length. (LSByte is written first. Write the number of bytes defined by SETUP_AW) 0xC3 R/W Receive address data pipe 2. Only LSB. MSBytes are equal to RX_ADDR_P1[39:8] 0xC4 R/W Receive address data pipe 3. Only LSB. MSBytes are equal to RX_ADDR_P1[39:8] 0xC5 R/W Receive address data pipe 4. Only LSB. MSBytes are equal to RX_ADDR_P1[39:8] 0xC6 R/W Receive address data pipe 5. Only LSB. MSBytes are equal to RX_ADDR_P1[39:8] Page 60 of 78 nRF24L01+ Product Specification Address (Hex) Mnemonic Bit RX_PW_P3 5:0 Reset Value 0 RX_PW_P4 Reserved RX_PW_P4 7:6 5:0 00 0 R/W Only '00' allowed R/W Number of bytes in RX payload in data pipe 4 (1 to 32 bytes). 0 Pipe not used 1 = 1 byte … 32 = 32 bytes RX_PW_P5 Reserved RX_PW_P5 7:6 5:0 00 0 R/W Only '00' allowed R/W Number of bytes in RX payload in data pipe 5 (1 to 32 bytes). 0 Pipe not used 1 = 1 byte … 32 = 32 bytes FIFO_STATUS Reserved TX_REUSE 7 6 0 0 TX_FULL 5 0 TX_EMPTY 4 1 Reserved RX_FULL 3:2 1 00 0 RX_EMPTY 0 1 15 16 17 Revision 1.0 Type Description R/W Number of bytes in RX payload in data pipe 3 (1 to 32 bytes). 0 Pipe not used 1 = 1 byte … 32 = 32 bytes FIFO Status Register R/W Only '0' allowed R Used for a PTX device Pulse the rfce high for at least 10µs to Reuse last transmitted payload. TX payload reuse is active until W_TX_PAYLOAD or FLUSH TX is executed. TX_REUSE is set by the SPI command REUSE_TX_PL, and is reset by the SPI commands W_TX_PAYLOAD or FLUSH TX R TX FIFO full flag. 1: TX FIFO full. 0: Available locations in TX FIFO. R TX FIFO empty flag. 1: TX FIFO empty. 0: Data in TX FIFO. R/W Only '00' allowed R RX FIFO full flag. 1: RX FIFO full. 0: Available locations in RX FIFO. R RX FIFO empty flag. 1: RX FIFO empty. 0: Data in RX FIFO. Page 61 of 78 nRF24L01+ Product Specification Address (Hex) N/A Mnemonic Bit ACK_PLD 255:0 Reset Value X N/A TX_PLD 255:0 X W N/A RX_PLD 255:0 X R 1C DYNPD Reserved DPL_P5 7:6 5 0 0 DPL_P4 4 0 DPL_P3 3 0 Revision 1.0 Type Description W Written by separate SPI command ACK packet payload to data pipe number PPP given in SPI command. Used in RX mode only. Maximum three ACK packet payloads can be pending. Payloads with same PPP are handled first in first out. Written by separate SPI command TX data payload register 1 - 32 bytes. This register is implemented as a FIFO with three levels. Used in TX mode only. Read by separate SPI command. RX data payload register. 1 - 32 bytes. This register is implemented as a FIFO with three levels. All RX channels share the same FIFO. Enable dynamic payload length R/W Only ‘00’ allowed R/W Enable dynamic payload length data pipe 5. (Requires EN_DPL and ENAA_P5) R/W Enable dynamic payload length data pipe 4. (Requires EN_DPL and ENAA_P4) R/W Enable dynamic payload length data pipe 3. (Requires EN_DPL and ENAA_P3) Page 62 of 78 nRF24L01+ Product Specification Address (Hex) 1D Mnemonic Bit DPL_P2 2 Reset Value 0 DPL_P1 1 0 DPL_P0 0 0 FEATURE Reserved EN_DPL EN_ACK_PAYd EN_DYN_ACK 7:3 2 1 0 0 0 0 0 Type Description R/W Enable dynamic payload length data pipe 2. (Requires EN_DPL and ENAA_P2) R/W Enable dynamic payload length data pipe 1. (Requires EN_DPL and ENAA_P1) R/W Enable dynamic payload length data pipe 0. (Requires EN_DPL and ENAA_P0) R/W R/W R/W R/W R/W Feature Register Only ‘00000’ allowed Enables Dynamic Payload Length Enables Payload with ACK Enables the W_TX_PAYLOAD_NOACK command a. Please take care when setting this parameter. If the ACK payload is more than 15 byte in 2Mbps mode the ARD must be 500µS or more, if the ACK payload is more than 5byte in 1Mbps mode the ARD must be 500µS or more. In 250kbps mode (even when the payload is not in ACK) the ARD must be 500µS or more. Please see section 7.4.2 on page 33 for more information. b. This is the time the PTX is waiting for an ACK packet before a retransmit is made. The PTX is in RX mode for 250µS (500µS in 250kbps mode) to wait for address match. If the address match is detected, it stays in RX mode to the end of the packet, unless ARD elapses. Then it goes to standby-II mode for the rest of the specified ARD. After the ARD it goes to TX mode and then retransmits the packet. c. The RX_DR IRQ is asserted by a new packet arrival event. The procedure for handling this interrupt should be: 1) read payload through SPI, 2) clear RX_DR IRQ, 3) read FIFO_STATUS to check if there are more payloads available in RX FIFO, 4) if there are more data in RX FIFO, repeat from step 1). d. If ACK packet payload is activated, ACK packets have dynamic payload lengths and the Dynamic Payload Length feature should be enabled for pipe 0 on the PTX and PRX. This is to ensure that they receive the ACK packets with payloads. If the ACK payload is more than 15 byte in 2Mbps mode the ARD must be 500µS or more, and if the ACK payload is more than 5 byte in 1Mbps mode the ARD must be 500µS or more. In 250kbps mode (even when the payload is not in ACK) the ARD must be 500µS or more. Table 28. Register map of nRF24L01+ Revision 1.0 Page 63 of 78 nRF24L01+ Product Specification 10 Peripheral RF Information This chapter describes peripheral circuitry and PCB layout requirements that are important for achieving optimum RF performance from the nRF24L01+. 10.1 Antenna output The ANT1 and ANT2 output pins provide a balanced RF output to the antenna. The pins must have a DC path to VDD_PA, either through a RF choke or through the center point in a balanced dipole antenna. A load of 15Ω+j88Ω is recommended for maximum output power (0dBm). Lower load impedance (for instance, 50Ω) can be obtained by fitting a simple matching network between the load and ANT1 and ANT2. A recommended matching network for 50Ω load impedance is described in chapter 11 on page 66. 10.2 Crystal oscillator A crystal used with the nRF24L01+ must fulfil the specifications in Table 11. on page 19. To achieve a crystal oscillator solution with low power consumption and fast start up time use a crystal with a low load capacitance specification. A lower C0 also gives lower current consumption and faster start up time, but can increase the cost of the crystal. Typically C0=1.5pF at a crystal specified for C0max=7.0pF. The crystal load capacitance, CL, is given by: CL = C1 '⋅C 2 ' C1 ' + C 2 ' , where C1’ = C1 + CPCB1 +CI1 and C2’ = C2 + CPCB2 + CI2 C1 and C2 are SMD capacitors, see the application schematics in Figure 32. on page 66. CPCB1 and CPCB2 are the layout parasitic on the circuit board. CI1 and CI2 are the internal capacitance load of the XC1 and XC2 pins respectively; the value is typically 1pF for both these pins. 10.3 nRF24L01+ crystal sharing with an MCU Follow the rules described in sections 10.3.1 and 10.3.2 when using an MCU to drive the crystal reference input XC1 of the nRF24L01+ transceiver. 10.3.1 Crystal parameters The MCU sets the requirement of load capacitance CL when it is driving the nRF24L01+ clock input. A frequency accuracy of ±60ppm is required to get a functional radio link. The nRF24L01+ loads the crystal by 1pF in addition to the PCB routing. 10.3.2 Input crystal amplitude and current consumption The input signal should not have amplitudes exceeding any rail voltage. Exceeding rail voltage excites the ESD structure and consequently, the radio performance degrades below specification. You must use an external DC block if you are testing the nRF24L01+ with a reference source that has no DC offset (which is usual with a RF source). Revision 1.0 Page 64 of 78 nRF24L01+ Product Specification XO_OUT Buffer: Sine to full swing Amplitude controlled current source Current starved inverter: XOSC core Vdd Vdd Rbias Vss Vss ESD ESD XC1 XC2 Figure 31. Principle of crystal oscillator The nRF24L01+ crystal oscillator is amplitude regulated. It is recommended to use an input signal larger than 0.4V-peak to achieve low current consumption and good signal-to-noise ratio when using an external clock. XC2 is not used and can be left as an open pin when clocked externally. 10.4 PCB layout and decoupling guidelines A well designed PCB is necessary to achieve good RF performance. A poor layout can lead to loss of performance or functionality. You can download a fully qualified RF layout for the nRF24L01+ and its surrounding components, including matching networks, from www.nordicsemi.no. A PCB with a minimum of two layers including a ground plane is recommended for optimum performance. The nRF24L01+ DC supply voltage should be decoupled as close as possible to the VDD pins with high performance RF capacitors, see Table 29. on page 67. Mounting a large surface mount capacitor (for example, 4.7µF ceramic) in parallel with the smaller value capacitors is recommended. The nRF24L01+ supply voltage should be filtered and routed separately from the supply voltages of any digital circuitry. Avoid long power supply lines on the PCB. All device grounds, VDD connections and VDD bypass capacitors must be connected as close as possible to the nRF24L01+ IC. The VSS pins should be connected directly to the ground plane for a PCB with a topside RF ground plane. We recommend having via holes as close as possible to the VSS pads for a PCB with a bottom ground plane. A minimum of one via hole should be used for each VSS pin. Full swing digital data or control signals should not be routed close to the crystal or the power supply lines. The exposed die attach pad is a ground pad connected to the IC substrate die ground and is intentionally not used in our layouts. We recommend to keep it unconnected. Revision 1.0 Page 65 of 78 nRF24L01+ Product Specification 11 Application example nRF24L01+ with single ended matching network crystal, bias resistor, and decoupling capacitors. C7 33nF 0402 C8 1nF 0402 1 2 3 4 5 CE CSN SCK MOSI MISO nRF24L01+ 15 14 13 12 11 VDD VSS ANT2 ANT1 VDD_PA IRQ VDD VSS XC2 XC1 CE CSN SCK MOSI MISO U1 VSS DVDD VDD VSS IREF C9 10nF 0402 R2 22K 0402 20 19 18 17 16 VDD C5 L3 L1 8.2nH 0402 50ohm, R 3.9nH 0402 1.5pF 0402 C6 1.0pF 0402 L2 2.7nH 0402 6 7 8 9 10 NRF24L01 IRQ C3 2.2nF 0402 X1 C4 4.7pF 0402 16 MHz R1 1M C1 22pF 0402 C2 22pF 0402 Figure 32. nRF24L01+ schematic for RF layouts with single ended 50Ω RF output Revision 1.0 Page 66 of 78 nRF24L01+ Product Specification Part a 22pF 22pFa 2.2nF 4.7pF 1.5pF 1,0pF 33nF 1nF 10nF 8,2nH 2.7nH 3,9nH Not mountedb 22kΩ nRF24L01+ 16MHz Designator C1 C2 C3 C4 C5 C6 C7 C8 C9 L1 L2 L3 R1 R2 U1 X1 Footprint 0402 0402 0402 0402 0402 0402 0402 0402 0402 0402 0402 0402 0402 0402 QFN20 4x4 Description NPO, +/- 2% NPO, +/- 2% X7R, +/- 10% NPO, +/- 0.25pF NPO, +/- 0.1pF NPO, +/- 0.1pF X7R, +/- 10% X7R, +/- 10% X7R, +/- 10% chip inductor +/- 5% chip inductor +/- 5% chip inductor +/- 5% +/-1% +/-60ppm, CL=12pF a. C1 and C2 must have values that match the crystals load capacitance, CL. b. The nRF24L01+ and nRF24L01 application example and BOM are the same with the exception of R1. R1 can be mounted for backward compatibility with nRF24L01. The use of a 1Mohm resistor externally does not have any impact on crystal performance. Table 29. Recommended components (BOM) in nRF24L01+ with antenna matching network 11.1 PCB layout examples Figure 33., Figure 34. and Figure 35. show a PCB layout example for the application schematic in Figure 32.. A double-sided FR-4 board of 1.6mm thickness is used. This PCB has a ground plane on the bottom layer. Additionally, there are ground areas on the component side of the board to ensure sufficient grounding of critical components. A large number of via holes connect the top layer ground areas to the bottom layer ground plane. Revision 1.0 Page 67 of 78 nRF24L01+ Product Specification + Figure 33. Top overlay (nRF24L01+ RF layout with single ended connection to PCB antenna and 0402 size passive components) Figure 34. Top layer (nRF24L01+ RF layout with single ended connection to PCB antenna and 0402 size passive components) Revision 1.0 Page 68 of 78 nRF24L01+ Product Specification Figure 35. Bottom layer (nRF24L01+ RF layout with single ended connection to PCB antenna and 0402 size passive components The nest figure (Figure 36., Figure 37. and Figure 38.) is for the SMA output to have a board for direct measurements at a 50Ω SMA connector. Figure 36. Top Overlay (Module with OFM crystal and SMA connector) Revision 1.0 Page 69 of 78 nRF24L01+ Product Specification Figure 37. Top Layer (Module with OFM crystal and SMA connector) Figure 38. Bottom Layer (Module with OFM crystal and SMA connector) Revision 1.0 Page 70 of 78 nRF24L01+ Product Specification 12 Mechanical specifications nRF24L01+ uses the QFN20 4x4 package, with matt tin plating. Revision 1.0 Page 71 of 78 nRF24L01+ Product Specification Package Type Saw QFN20 (4x4 mm) Min. Typ. Max A 0.80 0.85 0.95 A1 A3 0.00 0.02 0.20 0.05 REF. K 0.20 min. D/E e D2/E2 2.50 4.0 0.5 BSC 2.60 2.70 BSCa a. BSC: Basic Spacing between Centers, ref. JEDEC standard 95, page 4.17-11/A Figure 39. nRF24L01+ Package Outline Revision 1.0 Page 72 of 78 L 0.35 0.40 0.45 L1 0.15 max b 0.18 0.25 0.30 nRF24L01+ Product Specification 13 Ordering information 13.1 Package marking n 2 Y 13.2 R F A 4 L 0 1 Y W W L X + L Abbreviations Abbreviation nRF A X YY WW LL Definition Fixed text Variable Build Code, that is, unique code for production sites, package type and test platform “X" grade, that is, Engineering Samples (optional) 2 digit Year number 2 digit Week number 2 letter wafer lot number code 13.3 Product options 13.3.1 RF silicon Ordering code nRF24L01P-SAMPLE nRF24L01P-T nRF24L01P-R nRF24L01P-R7 Package Container 4x4mm 20-pin QFN, lead free (green) 4x4mm 20-pin QFN, lead free (green) 4x4mm 20-pin QFN, lead free (green) 4x4mm 20-pin QFN, lead free (green) Sample box MOQa 5 Tray 490 Tape and reel 4000 Tape and reel 1500 a. Minimum Order Quantity Table 30. nRF24L01+ RF silicon options 13.3.2 Development tools Type Number nRF24L01P-EVKIT nRF24L01P-UPGRADE nRF24L01P-MODULE-SMA nRF24L01P-MODULE-PCB Description nRF24L01+ Evaluation kit nRF24L01+ Upgrade kit for owners of nRF24L01EVKIT nRF24L01+ Evaluation kit module with SMA antenna nRF24L01+ Evaluation kit module with PCB antenna Table 31. nRF24L01+ solution options Revision 1.0 Page 73 of 78 Version nRF24L01+ Product Specification 14 Glossary of Terms Term ACK ACS AGC ART CD CE CLK CRC CSN ESB GFSK IM IRQ ISM LNA LSB LSByte Mbps MCU MISO MOSI MSB MSByte PCB PID PLD PRX PTX PWR_DWN PWR_UP RoHS RPD RX RX_DR SPI TX TX_DS Description Acknowledgement Adjacent Channel Selectivity Automatic Gain Control Auto Re-Transmit Carrier Detect Chip Enable Clock Cyclic Redundancy Check Chip Select NOT Enhanced ShockBurst™ Gaussian Frequency Shift Keying Intermodulation Interrupt Request Industrial-Scientific-Medical Low Noise Amplifier Least Significant Bit Least Significant Byte Megabit per second Microcontroller Unit Master In Slave Out Master Out Slave In Most Significant Bit Most Significant Byte Printed Circuit Board Packet Identity Bits Payload Primary RX Primary TX Power Down Power Up Restriction of use of Certain Hazardous Substances Received Power Detector Receive Receive Data Ready Serial Peripheral Interface Transmit Transmit Data Sent Table 32. Glossary Revision 1.0 Page 74 of 78 nRF24L01+ Product Specification Appendix A - Enhanced ShockBurst™ - Configuration and communication example Enhanced ShockBurst™ transmitting payload 1. 2. 3. 4. 5. 6. 7. Set the configuration bit PRIM_RX low. When the application MCU has data to transmit, clock the address for the receiving node (TX_ADDR) and payload data (TX_PLD) into nRF24L01+ through the SPI. The width of TX-payload is counted from the number of bytes written into the TX FIFO from the MCU. TX_PLD must be written continuously while holding CSN low. TX_ADDR does not have to be rewritten if it is unchanged from last transmit. If the PTX device shall receive acknowledge, configure data pipe 0 to receive the ACK packet. The RX address for data pipe 0 (RX_ADDR_P0) must be equal to the TX address (TX_ADDR) in the PTX device. For the example in Figure 14. on page 41 perform the following address settings for the TX5 device and the RX device: TX5 device: TX_ADDR = 0xB3B4B5B605 TX5 device: RX_ADDR_P0 = 0xB3B4B5B605 RX device: RX_ADDR_P5 = 0xB3B4B5B605 A high pulse on CE starts the transmission. The minimum pulse width on CE is 10µs. nRF24L01+ ShockBurst™: X Radio is powered up. X 16MHz internal clock is started. X RF packet is completed (see the packet description). X Data is transmitted at high speed (1Mbps or 2Mbps configured by MCU). If auto acknowledgement is activated (ENAA_P0=1) the radio goes into RX mode immediately, unless the NO_ACK bit is set in the received packet. If a valid packet is received in the valid acknowledgement time window, the transmission is considered a success. The TX_DS bit in the STATUS register is set high and the payload is removed from TX FIFO. If a valid ACK packet is not received in the specified time window, the payload is retransmitted (if auto retransmit is enabled). If the auto retransmit counter (ARC_CNT) exceeds the programmed maximum limit (ARC), the MAX_RT bit in the STATUS register is set high. The payload in TX FIFO is NOT removed. The IRQ pin is active when MAX_RT or TX_DS is high. To turn off the IRQ pin, reset the interrupt source by writing to the STATUS register (see Interrupt chapter). If no ACK packet is received for a packet after the maximum number of retransmits, no further packets can be transmitted before the MAX_RT interrupt is cleared. The packet loss counter (PLOS_CNT) is incremented at each MAX_RT interrupt. That is, ARC_CNT counts the number of retransmits that were required to get a single packet through. PLOS_CNT counts the number of packets that did not get through after the maximum number of retransmits. nRF24L01+ goes into standby-I mode if CE is low. Otherwise, next payload in TX FIFO is transmitted. If TX FIFO is empty and CE is still high, nRF24L01+ enters standby-II mode. If nRF24L01+ is in standby-II mode, it goes to standby-I mode immediately if CE is set low. Revision 1.0 Page 75 of 78 nRF24L01+ Product Specification Enhanced ShockBurst™ receive payload 1. 2. 3. 4. 5. 6. 7. 8. Select RX by setting the PRIM_RX bit in the CONFIG register to high. All data pipes that receive data must be enabled (EN_RXADDR register), enable auto acknowledgement for all pipes running Enhanced ShockBurst™ (EN_AA register), and set the correct payload widths (RX_PW_Px registers). Set up addresses as described in item 2 in the Enhanced ShockBurst™ transmitting payload example above. Start Active RX mode by setting CE high. After 130µs nRF24L01+ monitors the air for incoming communication. When a valid packet is received (matching address and correct CRC), the payload is stored in the RX-FIFO, and the RX_DR bit in STATUS register is set high. The IRQ pin is active when RX_DR is high. RX_P_NO in STATUS register indicates what data pipe the payload has been received in. If auto acknowledgement is enabled, an ACK packet is transmitted back, unless the NO_ACK bit is set in the received packet. If there is a payload in the TX_PLD FIFO, this payload is added to the ACK packet. MCU sets the CE pin low to enter standby-I mode (low current mode). MCU can clock out the payload data at a suitable rate through the SPI. nRF24L01+ is now ready for entering TX or RX mode or power down mode. Revision 1.0 Page 76 of 78 nRF24L01+ Product Specification Appendix B - Configuration for compatibility with nRF24XX How to setup nRF24L01+ to receive from an nRF2401/nRF2402/nRF24E1/nRF24E2: 1. 2. 3. 4. 5. 6. 7. 8. Use the same CRC configuration as the nRF2401/nRF2402/nRF24E1/nRF24E2. Set the PWR_UP and PRIM_RX bit to 1. Disable auto acknowledgement on the data pipe that is addressed. Use the same address width as the PTX device. Use the same frequency channel as the PTX device. Select data rate 1Mbps or 250kbps on both nRF24L01+ and nRF2401/nRF2402/nRF24E1/ nRF24E2. Set correct payload width on the data pipe that is addressed. Set CE high. How to setup nRF24L01+ to transmit to an nRF2401/nRF24E1: 1. 2. 3. 4. 5. 6. 7. 8. 9. Use the same CRC configuration as the nRF2401/nRF2402/nRF24E1/nRF24E2. Set the PRIM_RX bit to 0. Set the Auto Retransmit Count to 0 to disable the auto retransmit functionality. Use the same address width as the nRF2401/nRF2402/nRF24E1/nRF24E2. Use the same frequency channel as the nRF2401/nRF2402/nRF24E1/nRF24E2. Select data rate 1Mbps or 250kbps on both nRF24L01+ and nRF2401/nRF2402/nRF24E1/ nRF24E2. Set PWR_UP high. Clock in a payload that has the same length as the nRF2401/nRF2402/nRF24E1/nRF24E2 is configured to receive. Pulse CE to transmit the packet. Revision 1.0 Page 77 of 78 nRF24L01+ Product Specification Appendix C - Constant carrier wave output for testing The output power of a radio is a critical factor for achieving wanted range. Output power is also the first test criteria needed to qualify for all telecommunication regulations. Configuration 1. 2. 3. 4. 5. 6. Set PWR_UP = 1 and PRIM_RX = 0 in the CONFIG register. Wait 1.5ms PWR_UP->standby. In the RF register set: X CONT_WAVE = 1. X PLL_LOCK = 1. X RF_PWR. Set the wanted RF channel. Set CE high. Keep CE high as long as the carrier is needed. Note: Do not use REUSE_TX_PL together with CONT_WAVE=1. When both these registers are set the chip does not react when setting CE low. If however, both registers are set PWR_UP = 0 will turn TX mode off. The nRF24L01+ should now output an unmodulated centered carrier. Revision 1.0 Page 78 of 78
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