Product Info
Table Of Contents
- 20. Event Link Controller (ELC)
- 20.1 Overview
- 20.2 Register Descriptions
- 20.2.1 Event Link Control Register (ELCR)
- 20.2.2 Event Link Setting Register n (ELSRn) (n = 1 to 4, 7, 8, 10, 12, 14 to 16, 18 to 29)
- 20.2.3 Event Link Option Setting Register A (ELOPA)
- 20.2.4 Event Link Option Setting Register B (ELOPB)
- 20.2.5 Event Link Option Setting Register C (ELOPC)
- 20.2.6 Event Link Option Setting Register D (ELOPD)
- 20.2.7 Port Group Setting Register n (PGRn) (n = 1, 2)
- 20.2.8 Port Group Control Register n (PGCn) (n = 1, 2)
- 20.2.9 Port Buffer Register n (PDBFn) (n = 1, 2)
- 20.2.10 Event Link Port Setting Register m (PELm) (m = 0 to 3)
- 20.2.11 Event Link Software Event Generation Register (ELSEGR)
- 20.3 Operation
- 20.3.1 Relation between Interrupt Handling and Event Linking
- 20.3.2 Event Linkage
- 20.3.3 Operation of Peripheral Timer Modules When Event Signal is Input
- 20.3.4 Operation of CTSU When Event Signal is Input
- 20.3.5 Operation of A/D and D/A Converters When Event Signal is Input
- 20.3.6 I/O Port Operation When Event Signal is Input and Event Generation
- 20.3.7 Example of Procedure for Linking Events
- 20.4 Usage Notes
- 21. I/O Ports
- 21.1 Overview
- 21.2 I/O Port Configuration
- 21.3 Register Descriptions
- 21.3.1 Port Direction Register (PDR)
- 21.3.2 Port Output Data Register (PODR)
- 21.3.3 Port Input Data Register (PIDR)
- 21.3.4 Port Mode Register (PMR)
- 21.3.5 Open Drain Control Register 0 (ODR0)
- 21.3.6 Open Drain Control Register 1 (ODR1)
- 21.3.7 Pull-Up Control Register (PCR)
- 21.3.8 Drive Capacity Control Register (DSCR)
- 21.4 Initialization of the Port Direction Register (PDR)
- 21.5 Handling of Unused Pins
- 22. Multi-Function Pin Controller (MPC)
- 22.1 Overview
- 22.2 Register Descriptions
- 22.2.1 Write-Protect Register (PWPR)
- 22.2.2 P0n Pin Function Control Register (P0nPFS) (n = 3, 5, 7)
- 22.2.3 P1n Pin Function Control Registers (P1nPFS) (n = 4 to 7)
- 22.2.4 P2n Pin Function Control Register (P2nPFS) (n = 1, 2, 5 to 7)
- 22.2.5 P3n Pin Function Control Registers (P3nPFS) (n = 0, 1)
- 22.2.6 P4n Pin Function Control Registers (P4nPFS) (n = 0 to 7)
- 22.2.7 PBn Pin Function Control Registers (PBnPFS) (n = 0, 1, 3, 5, 7)
- 22.2.8 PCn Pin Function Control Registers (PCnPFS) (n = 0, 2 to 7)
- 22.2.9 PDn Pin Function Control Registers (PDnPFS) (n = 3)
- 22.2.10 PEn Pin Function Control Registers (PEnPFS) (n = 0 to 4)
- 22.2.11 PJn Pin Function Control Registers (PJnPFS) (n = 3)
- 22.3 Usage Notes
- 23. Multi-Function Timer Pulse Unit 2 (MTU2a)
- 23.1 Overview
- 23.2 Register Descriptions
- 23.2.1 Timer Control Register (TCR)
- 23.2.2 Timer Mode Register (TMDR)
- 23.2.3 Timer I/O Control Register (TIOR)
- 23.2.4 Timer Interrupt Enable Register (TIER)
- 23.2.5 Timer Status Register (TSR)
- 23.2.6 Timer Buffer Operation Transfer Mode Register (TBTM)
- 23.2.7 Timer Input Capture Control Register (TICCR)
- 23.2.8 Timer A/D Converter Start Request Control Register (TADCR)
- 23.2.9 Timer A/D Converter Start Request Cycle Set Registers A and B (TADCORA and TADCORB)
- 23.2.10 Timer A/D Converter Start Request Cycle Set Buffer Registers A and B (TADCOBRA and TADCOBRB)
- 23.2.11 Timer Counter (TCNT)
- 23.2.12 Timer General Register (TGR)
- 23.2.13 Timer Start Register (TSTR)
- 23.2.14 Timer Synchronous Register (TSYR)
- 23.2.15 Timer Read/Write Enable Register (TRWER)
- 23.2.16 Timer Output Master Enable Register (TOER)
- 23.2.17 Timer Output Control Register 1 (TOCR1)
- 23.2.18 Timer Output Control Register 2 (TOCR2)
- 23.2.19 Timer Output Level Buffer Register (TOLBR)
- 23.2.20 Timer Gate Control Register (TGCR)
- 23.2.21 Timer Subcounter (TCNTS)
- 23.2.22 Timer Dead Time Data Register (TDDR)
- 23.2.23 Timer Cycle Data Register (TCDR)
- 23.2.24 Timer Cycle Buffer Register (TCBR)
- 23.2.25 Timer Interrupt Skipping Set Register (TITCR)
- 23.2.26 Timer Interrupt Skipping Counter (TITCNT)
- 23.2.27 Timer Buffer Transfer Set Register (TBTER)
- 23.2.28 Timer Dead Time Enable Register (TDER)
- 23.2.29 Timer Waveform Control Register (TWCR)
- 23.2.30 Noise Filter Control Registers (NFCR)
- 23.2.31 Bus Master Interface
- 23.3 Operation
- 23.4 Interrupt Sources
- 23.5 Operation Timing
- 23.6 Usage Notes
- 23.6.1 Module Clock Stop Mode Setting
- 23.6.2 Count Clock Restrictions
- 23.6.3 Notes on Cycle Setting
- 23.6.4 Contention between TCNT Write and Clear Operations
- 23.6.5 Contention between TCNT Write and Increment Operations
- 23.6.6 Contention between TGR Write Operation and Compare Match
- 23.6.7 Contention between Buffer Register Write Operation and Compare Match
- 23.6.8 Contention between Buffer Register Write and TCNT Clear Operations
- 23.6.9 Contention between TGR Read Operation and Input Capture
- 23.6.10 Contention between TGR Write Operation and Input Capture
- 23.6.11 Contention between Buffer Register Write Operation and Input Capture
- 23.6.12 Contention between MTU2.TCNT Write Operation and Overflow/Underflow in Cascaded Operation
- 23.6.13 Counter Value When Count Operation is Stopped in Complementary PWM Mode
- 23.6.14 Buffer Operation Setting in Complementary PWM Mode
- 23.6.15 Buffer Operation and Compare Match Flags in Reset-Synchronized PWM Mode
- 23.6.16 Overflow Flags in Reset-Synchronized PWM Mode
- 23.6.17 Contention between Overflow/Underflow and Counter Clearing
- 23.6.18 Contention between TCNT Write Operation and Overflow/Underflow
- 23.6.19 Notes on Transition from Normal Mode or PWM Mode 1 to Reset-Synchronized PWM Mode
- 23.6.20 Output Level in Complementary PWM Mode or Reset-Synchronized PWM Mode
- 23.6.21 Interrupts during Periods in the Module Stop State
- 23.6.22 Simultaneous Input Capture in MTU1.TCNT and MTU2.TCNT in Cascade Connection
- 23.6.23 Notes When Complementary PWM Mode Output Protection Functions are Not Used
- 23.6.24 Points for Caution to Prevent Malfunctions in Synchronous Clearing for Complementary PWM Mode
- 23.6.25 Continuous Output of Interrupt Signal in Response to a Compare Match
- 23.6.26 Usage Notes on A/D Converter Delaying Function in Complementary PWM Mode
- 23.7 MTU Output Pin Initialization
- 23.8 Operations Linked by the ELC
- 24. Port Output Enable 2 (POE2a)
- 24.1 Overview
- 24.2 Register Descriptions
- 24.2.1 Input Level Control/Status Register 1 (ICSR1)
- 24.2.2 Output Level Control/Status Register 1 (OCSR1)
- 24.2.3 Input Level Control/Status Register 2 (ICSR2)
- 24.2.4 Software Port Output Enable Register (SPOER)
- 24.2.5 Port Output Enable Control Register 1 (POECR1)
- 24.2.6 Port Output Enable Control Register 2 (POECR2)
- 24.2.7 Input Level Control/Status Register 3 (ICSR3)
- 24.3 Operation
- 24.3.1 Input Level Detection Operation
- 24.3.2 Output-Level Compare Operation
- 24.3.3 High-Impedance Control Using Registers
- 24.3.4 High-Impedance Control on Detection of Stopped Oscillation
- 24.3.5 High-Impedance Control in Response to Receiving an Event Signal from the ELC
- 24.3.6 Release from the High-Impedance
- 24.4 Interrupts
- 24.5 Usage Notes
- 25. 16-Bit Timer Pulse Unit (TPUa)
- 25.1 Overview
- 25.2 Register Descriptions
- 25.2.1 Timer Control Register (TCR)
- 25.2.2 Timer Mode Register (TMDR)
- 25.2.3 Timer I/O Control Register (TIORH, TIORL, TIOR)
- 25.2.4 Timer Interrupt Enable Register (TIER)
- 25.2.5 Timer Status Register (TSR)
- 25.2.6 Timer Counter (TCNT)
- 25.2.7 Timer General Register A (TGRA), Timer General Register B (TGRB), Timer General Register C (TGRC), Timer General Register D (TGRD)
- 25.2.8 Timer Start Register (TSTR)
- 25.2.9 Timer Synchronous Register (TSYR)
- 25.2.10 Noise Filter Control Register (NFCR)
- 25.3 Operation
- 25.4 Interrupt Sources
- 25.5 DTC Activation
- 25.6 DMAC Activation
- 25.7 A/D Converter Activation
- 25.8 Operation Timing
- 25.9 Usage Notes
- 25.9.1 Module Stop Function Setting
- 25.9.2 Input Clock Restrictions
- 25.9.3 Notes on Cycle Setting
- 25.9.4 Conflict between TPUm.TCNT Write and Clear Operations
- 25.9.5 Conflict between TPUm.TCNT Write and Increment Operations
- 25.9.6 Conflict between TPUm.TGRy Write and Compare Match
- 25.9.7 Conflict between Buffer Register Write and Compare Match
- 25.9.8 Conflict between TPUm.TGRy Read and Input Capture
- 25.9.9 Conflict between TPUm.TGRy Write and Input Capture
- 25.9.10 Conflict between Buffer Register Write and Input Capture
- 25.9.11 TCNT Simultaneous Input Capture in Cascade Operation
- 25.9.12 Conflict between Overflow/Underflow and Counter Clearing
- 25.9.13 Conflict between TPUm.TCNT Write and Overflow/Underflow
- 25.9.14 Multiplexing of I/O Pins
- 25.9.15 Continuous Output of Compare-Match Pulse Interrupt Signal
- 25.9.16 Continuous Output of Input-Capture Pulse Interrupt Signal
- 25.9.17 Continuous Output of Underflow Pulse Interrupt Signal
- 26. 8-Bit Timer (TMR)
- 26.1 Overview
- 26.2 Register Descriptions
- 26.3 Operation
- 26.4 Operation Timing
- 26.5 Operation with Cascaded Connection
- 26.6 Interrupt Sources
- 26.7 Link Operation by ELC
- 26.8 Usage Notes
- 26.8.1 Module Stop State Setting
- 26.8.2 Notes on Setting Cycle
- 26.8.3 Conflict between TCNT Write and Counter Clear
- 26.8.4 Conflict between TCNT Write and Increment
- 26.8.5 Conflict between TCORA or TCORB Write and Compare Match
- 26.8.6 Conflict between Compare Matches A and B
- 26.8.7 Switching of Internal Clocks and TCNT Operation
- 26.8.8 Clock Source Setting with Cascaded Connection
- 26.8.9 Continuous Output of Compare Match Interrupt Signal
- 27. Compare Match Timer (CMT)
- 28. Realtime Clock (RTCe)
- 28.1 Overview
- 28.2 Register Descriptions
- 28.2.1 64-Hz Counter (R64CNT)
- 28.2.2 Second Counter (RSECCNT)/Binary Counter 0 (BCNT0)
- 28.2.3 Minute Counter (RMINCNT)/Binary Counter 1 (BCNT1)
- 28.2.4 Hour Counter (RHRCNT)/Binary Counter 2 (BCNT2)
- 28.2.5 Day-of-Week Counter (RWKCNT)/Binary Counter 3 (BCNT3)
- 28.2.6 Date Counter (RDAYCNT)
- 28.2.7 Month Counter (RMONCNT)
- 28.2.8 Year Counter (RYRCNT)
- 28.2.9 Second Alarm Register (RSECAR)/Binary Counter 0 Alarm Register (BCNT0AR)
- 28.2.10 Minute Alarm Register (RMINAR)/Binary Counter 1 Alarm Register (BCNT1AR)
- 28.2.11 Hour Alarm Register (RHRAR)/Binary Counter 2 Alarm Register (BCNT2AR)
- 28.2.12 Day-of-Week Alarm Register (RWKAR)/Binary Counter 3 Alarm Register (BCNT3AR)
- 28.2.13 Date Alarm Register (RDAYAR)/Binary Counter 0 Alarm Enable Register (BCNT0AER)
- 28.2.14 Month Alarm Register (RMONAR)/Binary Counter 1 Alarm Enable Register (BCNT1AER)
- 28.2.15 Year Alarm Register (RYRAR)/Binary Counter 2 Alarm Enable Register (BCNT2AER)
- 28.2.16 Year Alarm Enable Register (RYRAREN)/Binary Counter 3 Alarm Enable Register (BCNT3AER)
- 28.2.17 RTC Control Register 1 (RCR1)
- 28.2.18 RTC Control Register 2 (RCR2)
- 28.2.19 RTC Control Register 3 (RCR3)
- 28.2.20 Time Error Adjustment Register (RADJ)
- 28.2.21 Time Capture Control Register n (RTCCRn) (n = 0, 1)
- 28.2.22 Second Capture Register n (RSECCPn) (n = 0, 1)/BCNT0 Capture Register n (BCNT0CPn) (n = 0, 1)
- 28.2.23 Minute Capture Register n (RMINCPn) (n = 0, 1)/BCNT1 Capture Register n (BCNT1CPn) (n = 0, 1)
- 28.2.24 Hour Capture Register n (RHRCPn) (n = 0, 1)/BCNT2 Capture Register n (BCNT2CPn) (n = 0, 1)
- 28.2.25 Date Capture Register n (RDAYCPn) (n = 0, 1)/BCNT3 Capture Register n (BCNT3CPn) (n = 0, 1)
- 28.2.26 Month Capture Register n (RMONCPn) (n = 0, 1)
R01UH0823EJ0110 Rev.1.10 Page 413 of 1852
Nov 30, 2020
RX23W Group 19. Data Transfer Controller (DTCa)
19.6.2 Chain Transfer When the Counter is 0
The second data transfer is performed only when the transfer counter is set to 0 in the first data transfer, and the first data
transfer information is repeatedly changed in the second data transfer. Repeating this chain transfer enables transfers to
be repeated more than 256 times.
The following shows an example of configuring a 128-Kbyte input buffer to addresses 20 0000h to 21 FFFFh (where the
input buffer is set so that its lower address starts with 0000h). Figure 19.15 shows a chain transfer when the counter is 0.
(1) Set normal transfer mode for input data for the first data transfer. Set the following:
Transfer source address: Fixed, the CRA register is 0000h (65,536 times), the MRB.CHNE bit is 1 (chain transfer is
enabled), the MRB.CHNS bit is 1 (chain transfer is performed only when the transfer counter becomes 0), and the
MRB.DISEL bit is 0 (an interrupt request to the CPU is generated on completion of the specified number of data
transfers).
(2) Prepare the upper 8 bits (in this case, 21h and 20h) of the start address at every 65,536 times of the transfer
destination address for the first data transfer in another area (such as ROM).
(3) For the second data transfer, set repeat transfer mode (source is repeat area) for rewriting the transfer destination
address of the first data transfer. The transfer destination is the address where the upper 8 bits of the DAR register in
the first transfer information is allocated. In this case, set the MRB.CHNE bit to 0 (chain transfer is disabled) and
the MRB.DISEL bit to 0 (an interrupt request to the CPU is generated on completion of the specified number of data
transfers). In this case, set the transfer counter to 2.
(4) When a transfer request is accepted, the first data transfer is executed. When transfer is executed 65,536 times and
the transfer counter of the first data transfer becomes 0, the second data transfer is started and the upper 8 bits of the
transfer destination address of the first data transfer is set to 21h. At this time, the lower 16 bits of the transfer
destination address and the transfer counter of the first data transfer have become 0000h.
(5) In succession, when another transfer request is accepted, the first data transfer is executed. When transfer is
executed 65,536 times and the transfer counter of the first data transfer becomes 0, the second data transfer is started
and the upper 8 bits of the transfer destination address of the first data transfer is set to 20h. At this time, the lower
16 bits of the transfer destination address and the transfer counter of the first data transfer have become 0000h.
(6) Steps (4) and (5) above are repeated infinitely. Because the second data transfer is in repeat transfer mode, no
interrupt request to the CPU is generated.