Britney Dorval
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Yusheng-final_project_robot
Code for robot
Fork of Yusheng-final_project by
MRF24J40/MRF24J40.cpp
- Committer:
- csharer
- Date:
- 2016-11-10
- Revision:
- 6:ae3e6aefe908
File content as of revision 6:ae3e6aefe908:
/* mbed MRF24J40 (IEEE 802.15.4 tranceiver) Library * Copyright (c) 2011 Jeroen Hilgers * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #include "MRF24J40.h" // MRF20J40 Short address control register mapping. #define RXMCR 0x00 #define PANIDL 0x01 #define PANIDH 0x02 #define SADRL 0x03 #define SADRH 0x04 #define EADR0 0x05 #define EADR1 0x06 #define EADR2 0x07 #define EADR3 0x08 #define EADR4 0x09 #define EADR5 0x0a #define EADR6 0x0b #define EADR7 0x0c #define RXFLUSH 0x0d #define TXNMTRIG 0x1b #define TXSR 0x24 #define ISRSTS 0x31 #define INTMSK 0x32 #define GPIO 0x33 #define TRISGPIO 0x34 #define RFCTL 0x36 #define BBREG2 0x3A #define BBREG6 0x3E #define RSSITHCCA 0x3F // MRF20J40 Long address control register mapping. #define RFCTRL0 0x200 #define RFCTRL2 0x202 #define RFCTRL3 0x203 #define RFCTRL6 0x206 #define RFCTRL7 0x207 #define RFCTRL8 0x208 #define CLKINTCR 0x211 #define CLCCTRL 0x220 MRF24J40::MRF24J40(PinName mosi, PinName miso, PinName sck, PinName cs, PinName reset) ://, PinName irq, PinName wake) : mSpi(mosi, miso, sck), // mosi, miso, sclk mCs(cs), mReset(reset) // mIrq(irq), // mWake(wake) { mSpi.format(8, 0); // 8 bits, cpol=0; cpha=0 mSpi.frequency(500000); Reset(); } /* void MRF24J40::DebugDump(Serial &ser) { ser.printf("MRF24J40 registers:\r"); ser.printf("RXMCR=0x%X\r", MrfReadShort(RXMCR)); ser.printf("RXFLUSH=0x%X\r", MrfReadShort(RXFLUSH)); ser.printf("TXNMTRIG=0x%X\r", MrfReadShort(TXNMTRIG)); ser.printf("TXSR=0x%X\r", MrfReadShort(TXSR)); ser.printf("ISRSTS=0x%X\r", MrfReadShort(ISRSTS)); ser.printf("INTMSK=0x%X\r", MrfReadShort(INTMSK)); ser.printf("GPIO=0x%X\r", MrfReadShort(GPIO)); ser.printf("TRISGPIO=0x%X\r", MrfReadShort(TRISGPIO)); ser.printf("RFCTL=0x%X\r", MrfReadShort(RFCTL)); ser.printf("BBREG2=0x%X\r", MrfReadShort(BBREG2)); ser.printf("BBREG6=0x%X\r", MrfReadShort(BBREG6)); ser.printf("RSSITHCCA=0x%X\r", MrfReadShort(RSSITHCCA)); ser.printf("RFCTRL0=0x%X\r", MrfReadLong(RFCTRL0)); ser.printf("RFCTRL2=0x%X\r", MrfReadLong(RFCTRL2)); ser.printf("RFCTRL3=0x%X\r", MrfReadLong(RFCTRL3)); ser.printf("RFCTRL6=0x%X\r", MrfReadLong(RFCTRL6)); ser.printf("RFCTRL7=0x%X\r", MrfReadLong(RFCTRL7)); ser.printf("RFCTRL8=0x%X\r", MrfReadLong(RFCTRL8)); ser.printf("CLKINTCR=0x%X\r", MrfReadLong(CLKINTCR)); ser.printf("CLCCTRL=0x%X\r", MrfReadLong(CLCCTRL)); ser.printf("\r"); } */ void MRF24J40::Reset(void) { mCs = 1; // Pulse hardware reset. mReset = 0; wait_us(100); mReset = 1; wait_us(100); // Reset RF module. WriteShort(RFCTL, 0x04); WriteShort(RFCTL, 0x00); WriteShort(RFCTL, 0x00); WriteShort(PANIDL, 0xAA); WriteShort(PANIDH, 0xAA); WriteShort(SADRL, 0xAA); WriteShort(SADRH, 0xAA); // Flush RX fifo. WriteShort(RXFLUSH, 0x01); // Write MAC addresses here. We don't care. WriteLong(RFCTRL2, 0x80); // Enable RF PLL. WriteLong(RFCTRL3, 0x00); // Full power. WriteLong(RFCTRL6, 0x80); // Enable TX filter (recommended) WriteLong(RFCTRL8, 0x10); // Enhanced VCO (recommended) WriteShort(BBREG2,0x78); // Clear Channel Assesment use carrier sense. WriteShort(BBREG6,0x40); // Calculate RSSI for Rx packet. WriteShort(RSSITHCCA,0x00);// RSSI threshold for CCA. WriteLong(RFCTRL0, 0x00); // Channel 11. WriteShort(RXMCR, 0x01); // Don't check address upon reception. // MrfWriteShort(RXMCR, 0x00); // Check address upon reception. // Reset RF module with new settings. WriteShort(RFCTL, 0x04); WriteShort(RFCTL, 0x00); } void MRF24J40::Send(uint8_t *data, uint8_t length) { uint8_t i; WriteLong(0x000, 0); // No addresses in header. WriteLong(0x001, length); // 11 bytes for(i=0; i<length; i++) WriteLong(0x002+i, data[i]); WriteShort(TXNMTRIG, 0x01); } uint8_t MRF24J40::Receive(uint8_t *data, uint8_t maxLength) { uint8_t i, length; uint8_t lqi, rssi; if(ReadShort(ISRSTS)& 0x08) { length = ReadLong(0x300); lqi = ReadLong(0x301 + length); rssi = ReadLong(0x302 + length); for(i=0; i<length; i++) if(i<maxLength) *data++ = ReadLong(0x301 + (uint16_t)i); else ReadLong(0x301 + (uint16_t)i); if(length < maxLength) return length; } return 0; } uint8_t MRF24J40::ReadShort (uint8_t address) { uint8_t value; mCs = 0; wait_us(1); mSpi.write((address<<1) & 0x7E); wait_us(1); value = mSpi.write(0xFF); wait_us(1); mCs = 1; wait_us(1); return value; } void MRF24J40::WriteShort (uint8_t address, uint8_t data) { mCs = 0; wait_us(1); mSpi.write(((address<<1) & 0x7E) | 0x01); wait_us(1); mSpi.write(data); wait_us(1); mCs = 1; wait_us(1); } uint8_t MRF24J40::ReadLong (uint16_t address) { uint8_t value; mCs = 0; wait_us(1); mSpi.write((address>>3) | 0x80); wait_us(1); mSpi.write((address<<5) & 0xE0); wait_us(1); value = mSpi.write(0xFF); wait_us(1); mCs = 1; wait_us(1); return value; } void MRF24J40::WriteLong (uint16_t address, uint8_t data) { mCs = 0; wait_us(1); mSpi.write((address>>3) | 0x80); wait_us(1); mSpi.write(((address<<5) & 0xE0) | 0x10); wait_us(1); mSpi.write(data); wait_us(1); mCs = 1; wait_us(1); } void MRF24J40::SetChannel(uint8_t channel) { WriteLong(RFCTRL0, (channel & 0x0F)<<4 | 0x03); // Set channel, leave RFOPT bits at recommended //Reset the board by first writing a 4 to RFCTL, then writing a 0 WriteShort(RFCTL, 0x04); WriteShort(RFCTL, 0x00); wait(0.5); }