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EUSART

EUSART. Serial Communication. UART. Universal Asynchronous Receiver/Transmitter Receive: Convert serial to parallel ( SIPO) Transmit: Convert parallel to serial (PISO) Asynchronous: No clock; bytes sent in chunks. Start (0) and stop (1) signal for each byte. EUSART.

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EUSART

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  1. EUSART Serial Communication

  2. UART • Universal Asynchronous Receiver/Transmitter • Receive: Convert serial to parallel (SIPO) • Transmit: Convert parallel to serial (PISO) • Asynchronous: No clock; bytes sent in chunks. • Start (0) and stop (1) signal for each byte

  3. EUSART • Enhanced Universal Synchronous / Asynchronous Receiver/Transmitter • Synchronous: Constant stream of data matched with clock signal. • More efficient, no start/stop framing required. • Enhanced: Advanced features • Sleep mode/auto-wake • Calculate incoming baud rate • Error Detection • Full-duplex asynchronous, Half-duplex synchronous • 8 or 9 bit character length

  4. Flip-Flop • Flip-flops store a single bit of data. • SR NOR latch: Simplest type of flip flop.

  5. D Flip-Flop • Similar function, but uses clock to feed Data signal to Q in time with clock cycle.

  6. Receive • Shift Register (RSR): Cascade of flip-flops • Data written serially by shifting. • Upon filling register, all bits read simultaneously on clock cycle.

  7. Transmit • Altered shift register (TSR) reverses process. • All bits written to register simultaneously. • Bits shift to next flip-flop on cycles. • Last bit feeds output.

  8. Registers • TXSTA & RCSTA: Status registers. • Set modes. • TSR & RSR: Shift registers. • Not directly accessible. • TXREG & RCREG: Container for transmitted data. • BAUDCTL: 8-bit Baud Rate Control Register. • SPBRG & SPBRGH: 16-bit Baud Rate Generator.

  9. TXSTA – Transmit Status Register • CSRC - Clock Source Select bit - determines clock source. It is used only in synchronous mode. • 1 - Master mode. Clock is generated internally from Baud Rate Generator • 0 - Slave mode. Clock is generated from external source. • +TX9 - 9-bit Transmit Enable bit • 1 - 9-bit data transmission via EUSART system • 0 - 8-bit data transmission via EUSART system. • *TXEN - Transmit Enable bit • *1 - Transmission enabled • 0 - Transmission disabled. • *SYNC - EUSART Mode Select bit • 1 - EUSART operates in synchronous mode • 0 - EUSART operates in asynchronous mode. • SENDB - Send Break Character bit is only used in asynchronous mode and only in case it is required to observe LIN bus standard. • 1 - Sending Break character is enabled • 0 - Break character transmission is completed. • *BRGH - High Baud Rate Select bit determines baud rate in asynchronous mode. It does not affect EUSART in synchronous mode. • 1 - EUSART operates at high speed • 0 - EUSART operates at low speed. • TRMT - Transmit Shift Register Status bit • 1 - TSR register is empty • 0 - TSR register is full. • TX9D - Ninth bit of Transmit Data can be used as address or parity bit.

  10. RCSTA – Receive Status Register • *SPEN - Serial Port Enable bit • *1 - Serial port enabled. RX/DT and TX/CK pins are automatically configured as input and output respectively • 0 - Serial port disabled. • +RX9 - 9-bit Receive Enable bit • 1 - Receiving 9-bit data via EUSART system • 0 - Receiving 8-bit data via EUSART system. • SREN - Single Receive Enable bit is used only in synchronous mode when the microcontroller operates as master. • 1 - Single receive enabled • 0 - Single receive disable. • *CREN - Continuous Receive Enable bit acts differently depending on EUSART mode. • Asynchronous mode: • *1 - Receiver enabled • 0 - Receiver disabled. • Synchronous mode: • *1 - Enables continuous receive until the CREN bit is cleared • 0 - Disables continuous receive. • +ADDEN - Address Detect Enable bit is only used in address detect mode. • 1 - Enables address detection on 9-bit data receive • 0 - Disables address detection. The ninth bit can be used as parity bit. • ~FERR - Framing Error bit • 1 - On receive, Framing Error is detected • 0 - No framing error. • ~OERR - Overrun Error bit. • 1 - On receive, Overrun Error is detected • 0 - No overrun error. • RX9D - Ninth bit of Received Data can be used as address or parity bit.

  11. BAUDCTL – Baud Rate Control Register • *Bit 7: ABDOVF — Flag bit indicates time of overflow; sets rate. • 1 - Auto-baud timer overflowed • 0 - Auto-baud timer did not overflow. • Bit 6: RCIDL — Idle/Sleep; only used in asynchronous mode. • 1 - Receiver is idle • 0 - START bit has been received and receiving is in progress. • Bit 4: SCKP • Synchronous: indicate which Idle state is used for the data Clock (CK) • 1 - Synchronization on rising edge of the clock • 0 - Synchronization on falling edge of the clock. • Asynchronous: indicate transmit polarity. • 1 - Transmit inverted data to the RC6/TX/CK pin • 0 - Transmit non-inverted data to the same pin. • *Bit 3: BRG16 — Enable 16-bit • 1 – Enable 16-bit (disables BAUDCTL from setting rate). • 0 – Disable 16-bit mode. • Bit 1: WUE — Auto-wake/Interrupt • 1 - Receiver waits for a falling edge on the RC7/RX/DT pin to wake from sleep. • 0 - Receiver operates normally. • Bit 0: ABDEN — Reset Baud – auto-baud recalculation on next character (async only) • 1 - Auto-baud detect mode is enabled. Bit is automatically cleared on baud rate detect. • 0 - Auto-baud detect mode is disabled.

  12. Transmitter • Set Baud: BRGH (TXSTA) & BRG16 (BAUDCTL) • TXEN = 1: Enable transmitter (TXSTA) • SPEN = 1: Enable Serial Port (RCSTA) • TX/CK pin is output • SYNC: Synchronous-1 or Asynchronous-0 (TXSTA) • TXREG: Write data to be sent here. • TSR: Data automatically transferred to TSR shift register from which it is serialized and output. • TXREG is cleared and awaits new data to repeat transmission.

  13. Receiver • Set Baud: BRGH (TXSTA) & BRG16 (BAUDCTL) • CREN = 1: Enable receiver (RCSTA) • SPEN = 1: Enable Serial Port (RCSTA) • Input to RX/DT pin • SYNC: Synchronous-1 or Asynchronous-0 (TXSTA) • RX/DT serial pin data sent to RSR shift register. • RCREG: 8 or 9-bit data from RSR automatically transferred here. • Input data will be readable from RCREG register.

  14. TX/RC Interrupts • Interrupt represents each successive byte. • Enable TXIE or RCIE to enable interrupt. • Transmit • When TXREG is empty, TXIF flag is set. • FlagInterrupt: Send to TXREG • TXIF is reset until TXREG is re-emptied. • Receive • Upon filling RCREG, RCIF flag is set. • FlagInterrupt: Read RCREG • RCIF flag is reset until RCREG is re-filled.

  15. Example Code • Utilizing data received by EUSART. • http://pastebin.com/W1cP6bh8 • Interrupt Routine • If RCIF flag is set, read EUSART (RCREG). • Flag code when read. • Main function: • Enable interrupt. • Endless loop. If flagged, read new data and place in array.

  16. Address Detection • ADDEN bit (RCSTA) determines address size. • ADDEN = 1 allows 9-bit, excludes 8-bit • ADDEN = 0 disables address detection

  17. Errors • Framing Error: In asynchronous mode • Stop bit not received at expected time. • Enables FERR bit (RCSTA). • Interrupt not necessarily generated, simply informs of possibly incorrect data. • FERR is cleared by once data is read. • Overrun Error • RCREG is FIFO and can hold no more than two bytes. • Third byte while RCREG is still full • Enables OERR bit (RCSTA). • No more data received until OERR is manually cleared (clear CREN). • Manual clearing of SPEN (RCSTA) will reset entire EUSART.

  18. Reference • http://ww1.microchip.com/downloads/en/AppNotes/00944A.pdf • http://www.mikroe.com/chapters/view/7/chapter-6-serial-communication-modules/

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