Difference between revisions of "PIC32MX: SPI EEPROM"
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== |
== Overview == |
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EEPROM stands for stands for Electrically Erasable Programmable Read-Only Memory. It is a type of non-volitile memory that can be used to store little bits of data. Data will remain on EEPROM when power is disconnected, (like an external hardrive). The EEPROM chip must be reprogrammed in its entirety, and has a life span in the tens or hundreds of thousands of read/writes. |
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'''Do not erase this section!''' |
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You can use the PIC32 to communicate with an EEPROM chip using SPI. This page refers to the usage of a Serial EEPROM. |
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Your assignment is to interface to the SPI 25AA1024 EEPROM chip. |
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To test that the code data was writing and reading correctly, the attached code sends data to the EEPROM through SPI, then from the EEPROM back to the PIC, and out to a LED display screen. |
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== Overview == |
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EEPROM vs. Flash memory: The EEPROM erases the cell one by one, and only erases the 1's back to zero. Flash erases the whole block at once. Since erasing causes wear to the cell, the EEPROM will have a slightly longer lifetime. |
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Summarize briefly what the page is about. |
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== Circuit == |
== Circuit == |
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[[Image:spichip.jpg]] |
[[Image:spichip.jpg]] |
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For visual feedback the PIC32 was connected to and LCD screen(1602A1 USB-A/Mini-B5-06): |
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[[Image:LCD.jpg]] |
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== Timing == |
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Communication speed is determined by the clock signal and the Baud rate register (BRG). |
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<math>F_{clock} = \frac{F_{PB}}{2(BRG+1)}</math> |
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There is a delay of about 50 us when writing using the SpiChnPutC function, otherwise it will send/recieve one bit per clock cycle. Overall timing is limited by the EEPROM's internal write cycle (on the order of 1 ms). |
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== Code == |
== Code == |
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This first section of code sends and receives a single character (byte) of data |
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// This code checks the writing and reading of an EEPROM via SPI communication. Note: using this |
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//code, one can verify using the scope that the EEPROM can actually be read and the read content is just |
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//what is written into. |
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//this code also tells us that the transition between "write" and "read" is big. As a clock pulse is about |
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//several us(even with prescaler set to 1024), the transition is about ms. So in this case, |
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//if new data is written, and you read it soon afterwards(us), the EEPROM will not respond. |
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//note: lines of code like "//int mData=SPI2STAT;" is used to read the status register to debug |
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#include "Compiler.h" |
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#include "HardwareProfile.h" |
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#include <plib.h> |
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#include "LCD.h" |
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#define chipselect LATCbits.LATC1 |
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//manipulate /CS of EEPROM. Manipulation of EEPROM cannot be done by linking /SS of PIC and /CS of ROM. One |
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//can check this with a scope: built-in functions like SpiChnPutc() does not generate corresponding |
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//chipselect signal |
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int main() |
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{ |
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lcd_init(); |
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mInitAllLEDs(); |
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LATC |= 0b0000000000000010; //Use C1 of PIC to toggle /CS of ROM |
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TRISC &=0b1111111111111101; //intialize C1 as output |
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TRISGbits.TRISG7=1;// set G7 as digital input |
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char LCDbuffer[33]; // this will store the string for the LCD |
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int ENA= 0b00000110; //ROM write-enable instruction |
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int INS1=0b00000010; //ROM write instruction |
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int add1=0x00; //address byte 1 |
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int add2=0x11; //address byte 2 |
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int add3=0xee; //address byte 3 |
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int INS2=0b00000011; //ROM read instruction |
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int INS3=0b00000101; //read status register |
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int DIS = 0b00000100; //write disable sequence |
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while(1) //include a while loop to examine with a scope(cannot run single when there is 5ms time lag) |
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{ |
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IEC0CLR=0x03800000; //disable all interrupts |
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SPI2CON = 0; //resets SPI2 |
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int dump=SPI2BUF; //clears the receive buffer |
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IFS0CLR=0x03800000; //clear any existing event |
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SPI2STATCLR=0x40; //clears overflow flag |
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SpiChnOpen(2,SPI_CON_MSTEN| SPI_CON_MODE8|SPI_CON_ON, 1024); // divide fpb by 1024, configure the I/O ports. |
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//there is another way to open SPI channel, but essentially the same, intialize the SFRs |
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Delayus(50); |
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chipselect=0; //enable chip. the ROM starts up with /CS high |
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SpiChnPutC(2,ENA); |
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Delayus(100); //give enough time for the previous instruction to get executed |
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chipselect=1; //toggle /CS to properly set write enable, demanded by the ROM |
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Delayus(80); |
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chipselect=0; //enable chip again to initiate write sequence |
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Delayus(50); |
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SpiChnPutC(2,INS1); |
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SpiChnPutC(2,add1); |
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SpiChnPutC(2,add2); |
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SpiChnPutC(2,add3); |
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SpiChnPutC(2,0x50); //the previous five instructions writed byte 0x50 to address(1+2+3) |
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Delayus(200); // delay long enough for the sequence to be fully executed |
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chipselect=1; //deselect the chip to enable internal write sequence which is surprisingly slow!! |
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Delayus(5000); //yes! believe your eyes, 5ms. otherwise the chip would be 'busy' so that the following read sequence is 'dumped' |
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chipselect=0; //select chip to initiate reading |
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Delayus(50); |
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SpiChnPutC(2,INS2); |
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//reading instruction |
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SpiChnPutC(2,add1); |
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SpiChnPutC(2,add2); |
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SpiChnPutC(2,add3); |
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//read sequence, to read the very place where data was written |
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SpiChnPutC(2,0x00) //this line is necessary since the ROM needs clock signal to clock out the data. |
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//the reset of this code is hardly necessary for one to observe the write and read is executed. Because |
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//using a scope, one can observe the data is clocked out of the EEPROM the moment the address is given(so fast!) |
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//when this line is excuted, the data is put onto the SDI pins of PIC and as one bit is shifted out of |
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//SDO, a new bit is shifted into SDI |
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while(SPI2STAT!=0x849){} //wait until the TX buffer is empty, and enable data storage by clearing overflow |
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flag!!!without this line, one can get only 0xff |
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SPI2STATCLR = 0x40; //clear overflow flag |
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int receive = SPI2BUF; //since overflow is cleared, buffer is read so that new data can come in |
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Delayus(500); |
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int mData=SPI2STAT; //9 here, |
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receive = SPI2BUF; //read |
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Delayus(200); |
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chipselect=1; //end of reading sequence |
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sprintf(LCDbuffer, "\f%c", receive); // make the string 0x50 represents "P" in ASCII |
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putsLCD(LCDbuffer); // write the contents of the variable |
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} |
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} |
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This section of code is used to read and write strings of data to the EEPROM |
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//this code does string transmission |
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#include "Compiler.h" |
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#include "HardwareProfile.h" |
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#include <plib.h> |
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#include "LCD.h" |
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#define chipselect LATCbits.LATC1 |
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//manipulate /CS of EEPROM. Manipulation of EEPROM cannot be done by //linking /SS of PIC and /CS of ROM. One can check this with a scope: //built-in functions like SpiChnPutc() does not generate corresponding //chipselect signal |
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//function declaration |
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//void string(char *A,int s); |
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//this function does string, int s indicates the size of the string int here; |
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int ENA= 0b00000110; //ROM write-enable instruction |
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int INS1=0b00000010; //ROM write instruction |
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int INS2=0b00000011; //ROM read instruction |
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void write(unsigned char *data, int length); //actually address is 3-byte long but the first 7 bit dose not matter, we just make the first 8bit to be all 0s |
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void read(unsigned char *edata, int length); |
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int main() |
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{ |
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lcd_init(); |
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mInitAllLEDs(); |
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LATC |= 0b0000000000000010; //Use C1 of PIC to toggle /CS of ROM |
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TRISC &=0b1111111111111101; //intialize C1 as output |
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TRISGbits.TRISG7=1;// set G7 as digital input |
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char LCDbuffer[33]; // this will store the string for the LCD |
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short addr=0x0000; //initial writing address, first byte is set to zero and not displayed |
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IEC0CLR=0x03800000; //disable all interrupts |
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SPI2CON = 0; //resets SPI2 |
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int dump=SPI2BUF; //clears the receive buffer |
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IFS0CLR=0x03800000; //clear any existing event |
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SPI2STATCLR=0x40; //clears overflow flag |
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SpiChnOpen(2,SPI_CON_MSTEN| SPI_CON_MODE8|SPI_CON_ON, 1024); // divide fpb by 1024, configure the I/O ports. |
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unsigned char string[]="SPI SUCKS!!"; |
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int size=sizeof(string); |
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unsigned char readstring[size]; |
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//writing block, first enable writing |
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Delayus(50); |
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chipselect=0; //enable chip. the ROM starts up with /CS high |
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SpiChnPutC(2,ENA); |
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Delayus(100); //give enough time for the previous instruction to get executed |
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chipselect=1; //toggle /CS to properly set write enable, demanded by the ROM |
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Delayus(50); |
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Delayus(30); |
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chipselect=0; |
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write(string, size); |
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chipselect=1; |
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Delayus(5000); |
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//delay a long time for those data to get written, internal writ cycle |
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/*** |
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Below is the reading part |
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***/ |
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chipselect=0; //select chip to initiate reading |
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read(readstring,size); |
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chipselect=1; |
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//terminate reading sequence |
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sprintf(LCDbuffer, "\f%s", readstring); // make the string 0x50 represents "P" in ASCII |
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putsLCD(LCDbuffer); // write the contents of the variable |
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} |
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//functions |
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void write(unsigned char *edata, int length) |
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{ |
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// Send Data to eeprom to program one location |
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Delayus(50); |
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SpiChnPutC(2,INS1); //enable the chip and write "write" instruction |
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SpiChnPutC(2,0x00); //the first 8-bit address |
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SpiChnPutC(2,0x11); |
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SpiChnPutC(2,0x11); |
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while(length) |
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{ |
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SpiChnPutC(2,*edata); |
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edata++; |
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length--; |
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} |
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Delayus(20000); // delay long enough for the sequence to be fully executed |
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} |
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//below is the function that does sequential read |
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void read(unsigned char *data, int length) |
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{ |
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// Send Data to eeprom to program one location |
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Delayus(50); |
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SpiChnPutC(2,INS2); //enable the chip and write "read" instruction |
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SpiChnPutC(2,0x00); //the first 8-bit address |
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SpiChnPutC(2,0x11); |
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SpiChnPutC(2,0x11); //write the starting address |
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SpiChnPutC(2,0x00); |
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while(SPI2STAT!=0x849){} //wait until the TX buffer is empty, and enable data storage by clearing overflow flag!!! |
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SPI2STATCLR = 0x40; //clear overflow flag |
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int receive = SPI2BUF; //since overflow is cleared, buffer is read so that new data can come in |
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Delayus(500); |
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receive = SPI2BUF; //read |
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*data=receive; |
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data++; |
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length--; |
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//here=SPI2STAT; //008 here, means transmit buffer is empty |
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while(length) |
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{ |
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SpiChnPutC(2,0x00); |
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Delayus(500); |
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receive = SPI2BUF; //read |
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*data=receive; |
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data++; |
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length--; |
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} |
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Delayus(5000); |
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} |
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==Debugging== |
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If the readout on the LCD screen is not what was expected connect the EEPROM chip to a four channel oscilloscope and double check whether the data is being correctly transferred. |
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For example: the yellow channel 1 is clock signal, green channel 2 is PIC data output, blue channel 3 is /CS, purple channel 4 is pic data input |
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closed look at the EEPROM's output |
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[[Image:First.jpg]] |
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overview of reading |
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[[Image:Second.jpg]] |
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overview of writing |
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[[Image:Third.jpg]] |
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== Further Reading == |
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[[PIC32MX:_SPI_External_RAM]] |
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[[PIC32MX:_SPI_DAC]] |
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[[PIC32MX:_SPI_Communication_between_PIC32s]] |
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Where possible, make it a single piece of well-commented cut-and-pastable code, or at least make each function that way, so others can easily copy it. Most comments should be in the code itself; outside the code (on the wiki) should only be explanatory comments that are too cumbersome to include in the code. |
Latest revision as of 14:17, 1 March 2010
Overview
EEPROM stands for stands for Electrically Erasable Programmable Read-Only Memory. It is a type of non-volitile memory that can be used to store little bits of data. Data will remain on EEPROM when power is disconnected, (like an external hardrive). The EEPROM chip must be reprogrammed in its entirety, and has a life span in the tens or hundreds of thousands of read/writes.
You can use the PIC32 to communicate with an EEPROM chip using SPI. This page refers to the usage of a Serial EEPROM.
To test that the code data was writing and reading correctly, the attached code sends data to the EEPROM through SPI, then from the EEPROM back to the PIC, and out to a LED display screen.
EEPROM vs. Flash memory: The EEPROM erases the cell one by one, and only erases the 1's back to zero. Flash erases the whole block at once. Since erasing causes wear to the cell, the EEPROM will have a slightly longer lifetime.
Circuit
Include a schematic and give any part numbers. A photo of your circuit is OK, but not as a replacement for a schematic.
Connection schematic for 25AA1024 chip
For visual feedback the PIC32 was connected to and LCD screen(1602A1 USB-A/Mini-B5-06):
Timing
Communication speed is determined by the clock signal and the Baud rate register (BRG).
There is a delay of about 50 us when writing using the SpiChnPutC function, otherwise it will send/recieve one bit per clock cycle. Overall timing is limited by the EEPROM's internal write cycle (on the order of 1 ms).
Code
This first section of code sends and receives a single character (byte) of data
// This code checks the writing and reading of an EEPROM via SPI communication. Note: using this //code, one can verify using the scope that the EEPROM can actually be read and the read content is just //what is written into. //this code also tells us that the transition between "write" and "read" is big. As a clock pulse is about //several us(even with prescaler set to 1024), the transition is about ms. So in this case, //if new data is written, and you read it soon afterwards(us), the EEPROM will not respond. //note: lines of code like "//int mData=SPI2STAT;" is used to read the status register to debug #include "Compiler.h" #include "HardwareProfile.h" #include <plib.h> #include "LCD.h" #define chipselect LATCbits.LATC1 //manipulate /CS of EEPROM. Manipulation of EEPROM cannot be done by linking /SS of PIC and /CS of ROM. One //can check this with a scope: built-in functions like SpiChnPutc() does not generate corresponding //chipselect signal int main() { lcd_init(); mInitAllLEDs(); LATC |= 0b0000000000000010; //Use C1 of PIC to toggle /CS of ROM TRISC &=0b1111111111111101; //intialize C1 as output TRISGbits.TRISG7=1;// set G7 as digital input char LCDbuffer[33]; // this will store the string for the LCD int ENA= 0b00000110; //ROM write-enable instruction int INS1=0b00000010; //ROM write instruction int add1=0x00; //address byte 1 int add2=0x11; //address byte 2 int add3=0xee; //address byte 3 int INS2=0b00000011; //ROM read instruction int INS3=0b00000101; //read status register int DIS = 0b00000100; //write disable sequence while(1) //include a while loop to examine with a scope(cannot run single when there is 5ms time lag) { IEC0CLR=0x03800000; //disable all interrupts SPI2CON = 0; //resets SPI2 int dump=SPI2BUF; //clears the receive buffer IFS0CLR=0x03800000; //clear any existing event SPI2STATCLR=0x40; //clears overflow flag SpiChnOpen(2,SPI_CON_MSTEN| SPI_CON_MODE8|SPI_CON_ON, 1024); // divide fpb by 1024, configure the I/O ports. //there is another way to open SPI channel, but essentially the same, intialize the SFRs Delayus(50); chipselect=0; //enable chip. the ROM starts up with /CS high SpiChnPutC(2,ENA); Delayus(100); //give enough time for the previous instruction to get executed chipselect=1; //toggle /CS to properly set write enable, demanded by the ROM Delayus(80); chipselect=0; //enable chip again to initiate write sequence Delayus(50); SpiChnPutC(2,INS1); SpiChnPutC(2,add1); SpiChnPutC(2,add2); SpiChnPutC(2,add3); SpiChnPutC(2,0x50); //the previous five instructions writed byte 0x50 to address(1+2+3) Delayus(200); // delay long enough for the sequence to be fully executed chipselect=1; //deselect the chip to enable internal write sequence which is surprisingly slow!! Delayus(5000); //yes! believe your eyes, 5ms. otherwise the chip would be 'busy' so that the following read sequence is 'dumped' chipselect=0; //select chip to initiate reading Delayus(50); SpiChnPutC(2,INS2); //reading instruction SpiChnPutC(2,add1); SpiChnPutC(2,add2); SpiChnPutC(2,add3); //read sequence, to read the very place where data was written SpiChnPutC(2,0x00) //this line is necessary since the ROM needs clock signal to clock out the data. //the reset of this code is hardly necessary for one to observe the write and read is executed. Because //using a scope, one can observe the data is clocked out of the EEPROM the moment the address is given(so fast!) //when this line is excuted, the data is put onto the SDI pins of PIC and as one bit is shifted out of //SDO, a new bit is shifted into SDI while(SPI2STAT!=0x849){} //wait until the TX buffer is empty, and enable data storage by clearing overflow flag!!!without this line, one can get only 0xff SPI2STATCLR = 0x40; //clear overflow flag int receive = SPI2BUF; //since overflow is cleared, buffer is read so that new data can come in Delayus(500); int mData=SPI2STAT; //9 here, receive = SPI2BUF; //read Delayus(200); chipselect=1; //end of reading sequence sprintf(LCDbuffer, "\f%c", receive); // make the string 0x50 represents "P" in ASCII putsLCD(LCDbuffer); // write the contents of the variable } }
This section of code is used to read and write strings of data to the EEPROM
//this code does string transmission #include "Compiler.h" #include "HardwareProfile.h" #include <plib.h> #include "LCD.h" #define chipselect LATCbits.LATC1 //manipulate /CS of EEPROM. Manipulation of EEPROM cannot be done by //linking /SS of PIC and /CS of ROM. One can check this with a scope: //built-in functions like SpiChnPutc() does not generate corresponding //chipselect signal //function declaration //void string(char *A,int s); //this function does string, int s indicates the size of the string int here; int ENA= 0b00000110; //ROM write-enable instruction int INS1=0b00000010; //ROM write instruction int INS2=0b00000011; //ROM read instruction void write(unsigned char *data, int length); //actually address is 3-byte long but the first 7 bit dose not matter, we just make the first 8bit to be all 0s void read(unsigned char *edata, int length); int main() { lcd_init(); mInitAllLEDs(); LATC |= 0b0000000000000010; //Use C1 of PIC to toggle /CS of ROM TRISC &=0b1111111111111101; //intialize C1 as output TRISGbits.TRISG7=1;// set G7 as digital input char LCDbuffer[33]; // this will store the string for the LCD short addr=0x0000; //initial writing address, first byte is set to zero and not displayed IEC0CLR=0x03800000; //disable all interrupts SPI2CON = 0; //resets SPI2 int dump=SPI2BUF; //clears the receive buffer IFS0CLR=0x03800000; //clear any existing event SPI2STATCLR=0x40; //clears overflow flag SpiChnOpen(2,SPI_CON_MSTEN| SPI_CON_MODE8|SPI_CON_ON, 1024); // divide fpb by 1024, configure the I/O ports. unsigned char string[]="SPI SUCKS!!"; int size=sizeof(string); unsigned char readstring[size]; //writing block, first enable writing Delayus(50); chipselect=0; //enable chip. the ROM starts up with /CS high SpiChnPutC(2,ENA); Delayus(100); //give enough time for the previous instruction to get executed chipselect=1; //toggle /CS to properly set write enable, demanded by the ROM Delayus(50); Delayus(30); chipselect=0; write(string, size); chipselect=1; Delayus(5000); //delay a long time for those data to get written, internal writ cycle /*** Below is the reading part ***/ chipselect=0; //select chip to initiate reading read(readstring,size); chipselect=1; //terminate reading sequence sprintf(LCDbuffer, "\f%s", readstring); // make the string 0x50 represents "P" in ASCII putsLCD(LCDbuffer); // write the contents of the variable } //functions void write(unsigned char *edata, int length) { // Send Data to eeprom to program one location Delayus(50); SpiChnPutC(2,INS1); //enable the chip and write "write" instruction SpiChnPutC(2,0x00); //the first 8-bit address SpiChnPutC(2,0x11); SpiChnPutC(2,0x11); while(length) { SpiChnPutC(2,*edata); edata++; length--; } Delayus(20000); // delay long enough for the sequence to be fully executed } //below is the function that does sequential read void read(unsigned char *data, int length) { // Send Data to eeprom to program one location Delayus(50); SpiChnPutC(2,INS2); //enable the chip and write "read" instruction SpiChnPutC(2,0x00); //the first 8-bit address SpiChnPutC(2,0x11); SpiChnPutC(2,0x11); //write the starting address SpiChnPutC(2,0x00); while(SPI2STAT!=0x849){} //wait until the TX buffer is empty, and enable data storage by clearing overflow flag!!! SPI2STATCLR = 0x40; //clear overflow flag int receive = SPI2BUF; //since overflow is cleared, buffer is read so that new data can come in Delayus(500); receive = SPI2BUF; //read *data=receive; data++; length--; //here=SPI2STAT; //008 here, means transmit buffer is empty while(length) { SpiChnPutC(2,0x00); Delayus(500); receive = SPI2BUF; //read *data=receive; data++; length--; } Delayus(5000); }
Debugging
If the readout on the LCD screen is not what was expected connect the EEPROM chip to a four channel oscilloscope and double check whether the data is being correctly transferred. For example: the yellow channel 1 is clock signal, green channel 2 is PIC data output, blue channel 3 is /CS, purple channel 4 is pic data input
closed look at the EEPROM's output