Users Manual
Table Of Contents
- 37. Serial Sound Interface (SSI)
- 38. Serial Peripheral Interface (RSPIa)
- 38.1 Overview
- 38.2 Register Descriptions
- 38.2.1 RSPI Control Register (SPCR)
- 38.2.2 RSPI Slave Select Polarity Register (SSLP)
- 38.2.3 RSPI Pin Control Register (SPPCR)
- 38.2.4 RSPI Status Register (SPSR)
- 38.2.5 RSPI Data Register (SPDR)
- 38.2.6 RSPI Sequence Control Register (SPSCR)
- 38.2.7 RSPI Sequence Status Register (SPSSR)
- 38.2.8 RSPI Bit Rate Register (SPBR)
- 38.2.9 RSPI Data Control Register (SPDCR)
- 38.2.10 RSPI Clock Delay Register (SPCKD)
- 38.2.11 RSPI Slave Select Negation Delay Register (SSLND)
- 38.2.12 RSPI Next-Access Delay Register (SPND)
- 38.2.13 RSPI Control Register 2 (SPCR2)
- 38.2.14 RSPI Command Register m (SPCMDm) (m = 0 to 7)
- 38.3 Operation
- 38.3.1 Overview of RSPI Operations
- 38.3.2 Controlling RSPI Pins
- 38.3.3 RSPI System Configuration Examples
- 38.3.3.1 Single Master/Single Slave (with This MCU Acting as Master)
- 38.3.3.2 Single Master/Single Slave (with This MCU Acting as Slave)
- 38.3.3.3 Single Master/Multi-Slave (with This MCU Acting as Master)
- 38.3.3.4 Single Master/Multi-Slave (with This MCU Acting as Slave)
- 38.3.3.5 Multi-Master/Multi-Slave (with This MCU Acting as Master)
- 38.3.3.6 Master (Clock Synchronous Operation)/Slave (Clock Synchronous Operation) (with This MCU Acting as Master)
- 38.3.3.7 Master (Clock Synchronous Operation)/Slave (Clock Synchronous Operation) (with This MCU Acting as Slave)
- 38.3.4 Data Format
- 38.3.5 Transfer Format
- 38.3.6 Communications Operating Mode
- 38.3.7 Transmit Buffer Empty/Receive Buffer Full Interrupts
- 38.3.8 Error Detection
- 38.3.9 Initializing RSPI
- 38.3.10 SPI Operation
- 38.3.11 Clock Synchronous Operation
- 38.3.12 Loopback Mode
- 38.3.13 Self-Diagnosis of Parity Bit Function
- 38.3.14 Interrupt Sources
- 38.4 Link Operation by Event Linking
- 38.5 Usage Notes
- 39. CRC Calculator (CRC)
- 40. SD Host Interface (SDHIa)
- 40.1 Overview
- 40.2 Register Details
- 40.2.1 Command Register (SDCMD)
- 40.2.2 Argument Register (SDARG)
- 40.2.3 Data Stop Register (SDSTOP)
- 40.2.4 Block Count Register (SDBLKCNT)
- 40.2.5 Response Register 10 (SDRSP10), Response Register 32 (SDRSP32), Response Register 54 (SDRSP54), Response Register 76 (SDRSP76)
- 40.2.6 SD Status Register 1 (SDSTS1)
- 40.2.7 SD Status Register 2 (SDSTS2)
- 40.2.8 SD Interrupt Mask Register 1 (SDIMSK1)
- 40.2.9 SD Interrupt Mask Register 2 (SDIMSK2)
- 40.2.10 SDHI Clock Control Register (SDCLKCR)
- 40.2.11 Transfer Data Size Register (SDSIZE)
- 40.2.12 Card Access Option Register (SDOPT)
- 40.2.13 SD Error Status Register 1 (SDERSTS1)
- 40.2.14 SD Error Status Register 2 (SDERSTS2)
- 40.2.15 SD Buffer Register (SDBUFR)
- 40.2.16 SDIO Mode Control Register (SDIOMD)
- 40.2.17 SDIO Status Register (SDIOSTS)
- 40.2.18 SDIO Interrupt Mask Register (SDIOIMSK)
- 40.2.19 DMA Transfer Enable Register (SDDMAEN)
- 40.2.20 SDHI Software Reset Register (SDRST)
- 40.2.21 Swap Control Register (SDSWAP)
- 40.3 SDHI Operation
- 40.3.1 Data Block Format of the SD Card
- 40.3.2 SD Buffer and the SDBUFR Register
- 40.3.3 SD Card Detection
- 40.3.4 SD Card Write Protection
- 40.3.5 Communication Errors and Timeouts
- 40.3.6 Examples of Issuing a Command
- 40.3.6.1 Command Absent of Response Reception and Data Transfer
- 40.3.6.2 Command Absent of Data Transfer
- 40.3.6.3 Single Block Read Command (CMD17)
- 40.3.6.4 Single Block Write Command (CMD24)
- 40.3.6.5 Multi-Block Read Command (CMD18)
- 40.3.6.6 Multi-Block Write Command (CMD25)
- 40.3.6.7 IO_RW_DIRECT Command (CMD52)
- 40.3.6.8 IO_RW_EXTENDED Command (CMD53 (Multi-Block Read))
- 40.3.6.9 IO_RW_EXTENDED (CMD53 Multi-Block Write)
- 40.3.6.10 DMA Transfer
- 40.4 Interrupts
- 40.5 Notes on Using the SDHI
- 40.5.1 Illegal Read Access During a Multi-Block Read and How To Avoid It
- 40.5.2 SDBUFR Register Illegal Write Error
- 40.5.3 Automatic Control of the SDHI Clock Output
- 40.5.4 Restrictions on Setting the C52PUB Bit During a Multi-Block Write Sequence
- 40.5.5 Note on Setting the SDCLKCR Register
- 40.5.6 Writing to the SDSTOP Register During a Multi-Block Read Sequence
- 40.5.7 Controlling Module Operation
- 41. Bluetooth Low Energy (BLE)
- 42. Trusted Secure IP (TSIP-Lite)
- 43. Capacitive Touch Sensing Unit (CTSU)
- 43.1 Overview
- 43.2 Register Descriptions
- 43.2.1 CTSU Control Register 0 (CTSUCR0)
- 43.2.2 CTSU Control Register 1 (CTSUCR1)
- 43.2.3 CTSU Synchronous Noise Reduction Setting Register (CTSUSDPRS)
- 43.2.4 CTSU Sensor Stabilization Wait Control Register (CTSUSST)
- 43.2.5 CTSU Measurement Channel Register 0 (CTSUMCH0)
- 43.2.6 CTSU Measurement Channel Register 1 (CTSUMCH1)
- 43.2.7 CTSU Channel Enable Control Register 0 (CTSUCHAC0)
- 43.2.8 CTSU Channel Enable Control Register 1 (CTSUCHAC1)
- 43.2.9 CTSU Channel Enable Control Register 2 (CTSUCHAC2)
- 43.2.10 CTSU Channel Enable Control Register 3 (CTSUCHAC3)
- 43.2.11 CTSU Channel Enable Control Register 4 (CTSUCHAC4)
- 43.2.12 CTSU Channel Transmit/Receive Control Register 0 (CTSUCHTRC0)
- 43.2.13 CTSU Channel Transmit/Receive Control Register 1 (CTSUCHTRC1)
- 43.2.14 CTSU Channel Transmit/Receive Control Register 2 (CTSUCHTRC2)
- 43.2.15 CTSU Channel Transmit/Receive Control Register 3 (CTSUCHTRC3)
- 43.2.16 CTSU Channel Transmit/Receive Control Register 4 (CTSUCHTRC4)
- 43.2.17 CTSU High-Pass Noise Reduction Control Register (CTSUDCLKC)
- 43.2.18 CTSU Status Register (CTSUST)
- 43.2.19 CTSU High-Pass Noise Reduction Spectrum Diffusion Control Register (CTSUSSC)
- 43.2.20 CTSU Sensor Offset Register 0 (CTSUSO0)
- 43.2.21 CTSU Sensor Offset Register 1 (CTSUSO1)
- 43.2.22 CTSU Sensor Counter (CTSUSC)
- 43.2.23 CTSU Reference Counter (CTSURC)
- 43.2.24 CTSU Error Status Register (CTSUERRS)
- 43.3 Operation
- 43.4 Usage Notes
- 44. 12-Bit A/D Converter (S12ADE)
- 44.1 Overview
- 44.2 Register Descriptions
- 44.2.1 A/D Data Registers y (ADDRy) (y = 0 to 7, 16 to 20, 27), A/D Data Duplication Register (ADDBLDR), A/D Temperature Sensor Data Register (ADTSDR), A/D Internal Reference Voltage Data Register (ADOCDR)
- 44.2.2 A/D Self-Diagnosis Data Register (ADRD)
- 44.2.3 A/D Control Register (ADCSR)
- 44.2.4 A/D Channel Select Register A0 (ADANSA0)
- 44.2.5 A/D Channel Select Register A1 (ADANSA1)
- 44.2.6 A/D Channel Select Register B0 (ADANSB0)
- 44.2.7 A/D Channel Select Register B1 (ADANSB1)
- 44.2.8 A/D-Converted Value Addition/Average Function Select Register 0 (ADADS0)
- 44.2.9 A/D-Converted Value Addition/Average Function Select Register 1 (ADADS1)
- 44.2.10 A/D-Converted Value Addition/Average Count Select Register (ADADC)
- 44.2.11 A/D Control Extended Register (ADCER)
- 44.2.12 A/D Conversion Start Trigger Select Register (ADSTRGR)
- 44.2.13 A/D Conversion Extended Input Control Register (ADEXICR)
- 44.2.14 A/D Sampling State Register n (ADSSTRn) (n = 0 to 7, L, T, O)
- 44.2.15 A/D Disconnection Detection Control Register (ADDISCR)
- 44.2.16 A/D Event Link Control Register (ADELCCR)
- 44.2.17 A/D Group Scan Priority Control Register (ADGSPCR)
- 44.2.18 A/D Compare Function Control Register (ADCMPCR)
- 44.2.19 A/D Compare Function Window A Channel Select Register 0 (ADCMPANSR0)
- 44.2.20 A/D Compare Function Window A Channel Select Register 1 (ADCMPANSR1)
- 44.2.21 A/D Compare Function Window A Extended Input Select Register (ADCMPANSER)
- 44.2.22 A/D Compare Function Window A Comparison Condition Setting Register 0 (ADCMPLR0)
- 44.2.23 A/D Compare Function Window A Comparison Condition Setting Register 1 (ADCMPLR1)
- 44.2.24 A/D Compare Function Window A Extended Input Comparison Condition Setting Register (ADCMPLER)
- 44.2.25 A/D Compare Function Window A Lower-Side Level Setting Register (ADCMPDR0)
- 44.2.26 A/D Compare Function Window A Upper-Side Level Setting Register (ADCMPDR1)
- 44.2.27 A/D Compare Function Window A Channel Status Register 0 (ADCMPSR0)
- 44.2.28 A/D Compare Function Window A Channel Status Register 1 (ADCMPSR1)
- 44.2.29 A/D Compare Function Window A Extended Input Channel Status Register (ADCMPSER)
- 44.2.30 A/D High-Potential/Low-Potential Reference Voltage Control Register (ADHVREFCNT)
- 44.2.31 A/D Compare Function Window A/B Status Monitor Register (ADWINMON)
- 44.2.32 A/D Compare Function Window B Channel Select Register (ADCMPBNSR)
- 44.2.33 A/D Compare Function Window B Lower-Side Level Setting Register (ADWINLLB)
- 44.2.34 A/D Compare Function Window B Upper-Side Level Setting Register (ADWINULB)
- 44.2.35 A/D Compare Function Window B Channel Status Register (ADCMPBSR)
- 44.2.36 A/D Data Storage Buffer Register n (ADBUFn) (n = 0 to 15)
R01UH0823EJ0110 Rev.1.10 Page 1274 of 1852
Nov 30, 2020
RX23W Group 36. CAN Module (RSCAN)
• Bus off: Isolated from CAN communication.
When the CTRL.CHMDC[1:0] bits are set to 00b, the channel transitions to channel communication mode. After that,
when 11 consecutive recessive bits have been detected, the STSL.COMSTS flag becomes 1 (communication is ready)
and transmission and reception are enabled on the CAN network as an active node. At this time, transmission and
reception of messages can be started.
(5) Bus Off State
A channel transitions to the bus off state according to the transmit/receive error counter increment/decrement rules of the
ISO 11898-1 standard.
How to return from the bus off state is set by the CTRH.BOM[1:0] bits.
• When CTRH.BOM[1:0] = 00b:
Bus off recovery is compliant with the ISO 11898-1 standard. After 11 consecutive recessive bits have been
detected 128 times, a channel returns from the bus off state to the CAN communication ready state (error active
state).
At that time, the STSH.TEC[7:0] and STSH.REC[7:0] flags are initialized to 00h and the ERFLL.BORF flag
becomes 1 (bus off recovery is detected). When the CTRL.CHMDC[1:0] bits are set to 10b (channel halt mode) in
the bus off state, the channel transitions to channel halt mode after bus off recovery has been completed (11
consecutive recessive bits have been detected 128 times).
• When CTRH.BOM[1:0] = 01b:
When a channel transitions to the bus off state, the CTRL.CHMDC[1:0] bits are set to 10b and the channel
transitions to channel halt mode. At that time, the STSH.TEC[7:0] and STSH.REC[7:0] flags are initialized to 00h
but the ERFLL.BORF flag is not set to 1.
• When CTRH.BOM[1:0] = 10b:
When a channel has transitioned to the bus off state, the CTRL.CHMDC[1:0] bits are set to 10b. After bus off
recovery has been completed (11 consecutive recessive bits have been detected 128 times), the channel transitions
to channel halt mode. At that time, the STSH.TEC[7:0] and STSH.REC[7:0] flags are initialized to 00h and the
ERFLL.BORF flag becomes 1.
• When CTRH.BOM[1:0] = 11b:
When the CHMDC[1:0] bits are set to 10b in the bus off state, the channel transitions to channel halt mode before
bus off recovery is completed. At that time, the STSH.TEC[7:0] and STSH.REC[7:0] flags are initialized to 00h but
the ERFLL.BORF flag is not set to 1.
However, the BORF flag becomes 1 if a CAN module transitions to error active state (by detecting 128 times of 11
consecutive recessive bits) before the CTRL.CHMDC[1:0] bits are set to 10b.
If the channel transitions to channel halt mode simultaneously when the program writes a value to the
CTRL.CHMDC[1:0] bits, writing by the program takes precedence. An automatic transition to channel halt mode when
the CTRH.BOM[1:0] bits are set to 01b or 10b is made only when the CTRL.CHMDC[1:0] bits are 00b (channel
communication mode).
Furthermore, setting the CTRL.RTBO bit to 1 allows forcible return from the bus off state. As soon as the CTRL.RTBO
bit is set to 1, the state changes to the error active state. After 11 consecutive recessive bits have been detected, the
condition of CAN module becomes ready for communication. In this case, the ERFLL.BORF flag is not set to 1 and the
STSH.TEC[7:0] and STSH.REC[7:0] flags are initialized to 00h. Write 1 to the CTRL.RTBO bit when the
CTRH.BOM[1:0] value is 00b.