Users Manual
Table Of Contents
- 45. 12-Bit D/A Converter (R12DAA)
- 46. Temperature Sensor (TEMPSA)
- 47. Comparator B (CMPBa)
- 47.1 Overview
- 47.2 Register Descriptions
- 47.2.1 Comparator B1 Control Register 1 (CPB1CNT1)
- 47.2.2 Comparator B1 Control Register 2 (CPB1CNT2)
- 47.2.3 Comparator B1 Flag Register (CPB1FLG)
- 47.2.4 Comparator B1 Interrupt Control Register (CPB1INT)
- 47.2.5 Comparator B1 Filter Select Register (CPB1F)
- 47.2.6 Comparator B1 Mode Select Register (CPB1MD)
- 47.2.7 Comparator B1 Reference Input Voltage Select Register (CPB1REF)
- 47.2.8 Comparator B1 Output Control Register (CPB1OCR)
- 47.3 Operation
- 47.4 Comparator B2 and Comparator B3 Interrupts
- 47.5 Usage Note
- 48. Data Operation Circuit (DOC)
- 49. RAM
- 50. Flash Memory (FLASH)
- 50.1 Overview
- 50.2 ROM Area and Block Configuration
- 50.3 E2 DataFlash Area and Block Configuration
- 50.4 Register Descriptions
- 50.4.1 E2 DataFlash Control Register (DFLCTL)
- 50.4.2 Flash P/E Mode Entry Register (FENTRYR)
- 50.4.3 Protection Unlock Register (FPR)
- 50.4.4 Protection Unlock Status Register (FPSR)
- 50.4.5 Flash P/E Mode Control Register (FPMCR)
- 50.4.6 Flash Initial Setting Register (FISR)
- 50.4.7 Flash Reset Register (FRESETR)
- 50.4.8 Flash Area Select Register (FASR)
- 50.4.9 Flash Control Register (FCR)
- 50.4.10 Flash Extra Area Control Register (FEXCR)
- 50.4.11 Flash Processing Start Address Register H (FSARH)
- 50.4.12 Flash Processing Start Address Register L (FSARL)
- 50.4.13 Flash Processing End Address Register H (FEARH)
- 50.4.14 Flash Processing End Address Register L (FEARL)
- 50.4.15 Flash Write Buffer Register n (FWBn) (n = 0 to 3)
- 50.4.16 Flash Status Register 0 (FSTATR0)
- 50.4.17 Flash Status Register 1 (FSTATR1)
- 50.4.18 Flash Error Address Monitor Register H (FEAMH)
- 50.4.19 Flash Error Address Monitor Register L (FEAML)
- 50.4.20 Flash Start-Up Setting Monitor Register (FSCMR)
- 50.4.21 Flash Access Window Start Address Monitor Register (FAWSMR)
- 50.4.22 Flash Access Window End Address Monitor Register (FAWEMR)
- 50.4.23 Unique ID Register n (UIDRn) (n = 0 to 3)
- 50.5 Start-Up Program Protection
- 50.6 Area Protection
- 50.7 Programming and Erasure
- 50.8 Boot Mode
- 50.9 Flash Memory Protection
- 50.10 Communication Protocol
- 50.10.1 State Transition in Boot Mode (SCI Interface)
- 50.10.2 Command and Response Configuration
- 50.10.3 Response to Undefined Commands
- 50.10.4 Boot Mode Status Inquiry
- 50.10.5 Inquiry Commands
- 50.10.6 Setting Commands
- 50.10.7 ID Code Authentication Command
- 50.10.8 Program/Erase Commands
- 50.10.9 Read-Check Commands
- 50.11 Serial Programmer Operation in Boot Mode (SCI Interface)
- 50.11.1 Bit Rate Automatic Adjustment Procedure
- 50.11.2 Procedure to Receive the MCU Information
- 50.11.3 Procedure to Select the Device and Change the Bit Rate
- 50.11.4 Procedure for Transition to the Program/Erase Host Command Wait State
- 50.11.5 Procedure to Unlock Boot Mode ID Code Protection
- 50.11.6 Procedure to Erase the User Area and Data Area
- 50.11.7 Procedure to Program the User Area and Data Area
- 50.11.8 Procedure to Check Data in the User Area
- 50.11.9 Procedure to Check Data in the Data Area
- 50.11.10 Procedure to Set the Access Window in the User Area
- 50.12 Rewriting by Self-Programming
- 50.13 Usage Notes
- 50.14 Usage Notes in Boot Mode
- 51. Electrical Characteristics
- 51.1 Absolute Maximum Ratings
- 51.2 DC Characteristics
- 51.3 AC Characteristics
- 51.3.1 Clock Timing
- 51.3.2 Reset Timing
- 51.3.3 Timing of Recovery from Low Power Consumption Modes
- 51.3.4 Control Signal Timing
- 51.3.5 Timing of On-Chip Peripheral Modules
- 51.3.5.1 Timing of I/O Ports
- 51.3.5.2 Timing of MTU/TPU
- 51.3.5.3 Timing of POE
- 51.3.5.4 Timing of TMR
- 51.3.5.5 Timing of SCI
- 51.3.5.6 Timing of RIIC
- 51.3.5.7 Timing of RSPI
- 51.3.5.8 Timing of SSI
- 51.3.5.9 Timing of SDHI
- 51.3.5.10 Timing of A/D Converter Trigger
- 51.3.5.11 Timing of CAC
- 51.3.5.12 Timing of CLKOUT
- 51.3.5.13 Timing of CLKOUT_RF
- 51.4 USB Characteristics
- 51.5 A/D Conversion Characteristics
- 51.6 D/A Conversion Characteristics
- 51.7 Temperature Sensor Characteristics
- 51.8 Comparator Characteristics
- 51.9 CTSU Characteristics
- 51.10 Characteristics of Power-On Reset Circuit and Voltage Detection Circuit
- 51.11 Oscillation Stop Detection Timing
- 51.12 Battery Backup Function Characteristics
- 51.13 ROM (Flash Memory for Code Storage) Characteristics
- 51.14 E2 DataFlash Characteristics (Flash Memory for Data Storage)
- 51.15 BLE Characteristics
- 51.16 Usage Notes
- Appendix 1. Port States in Each Processing Mode
- Appendix 2. Package Dimensions
- REVISION HISTORY
- Colophon
- Address List
- Back cover
R01UH0823EJ0110 Rev.1.10 Page 1627 of 1852
Nov 30, 2020
RX23W Group 44. 12-Bit A/D Converter (S12ADE)
Figure 44.23 Scan Conversion Timing (Activated by Asynchronous Trigger)
44.3.7 Usage Example of A/D Data Register Automatic Clearing Function
Setting the ADCER.ACE bit to 1 automatically clears the A/D data registers (ADDRy, ADRD, ADTSDR, ADOCDR,
ADDBLDR) to 0000h when the A/D data registers are read by the CPU, DTC, or DMACA.
The ring buffer (ADBUFn: n = 0 to 15) is not subject to auto-clearing.
This function enables detection of update failures of the A/D data registers (ADDRy, ADRD, ADTSDR, ADOCDR,
ADDBLDR). The following describes the examples in which the function to automatically clear the ADDRy register is
enabled and disabled.
In a case where the ADCER.ACE bit is 0 (automatic clearing disabled), if the A/D conversion result (0222h) is not
written to the ADDRy register for some reason, the old data (0111h) will be the ADDRy value. Furthermore, if this
ADDRy value is read into a general register using an A/D scan end interrupt, the old data (0111h) can be saved in the
general register. When checking whether there is an update failure, it is necessary to frequently save the old data in the
RAM or a general register.
In a case where the ADCER.ACE bit is 1 (automatic clearing enabled), when ADDRy = 0111h is read by the CPU, DTC,
or DMACA, ADDRy is automatically cleared to 0000h. After that, if the A/D conversion result 0222h cannot be
transferred to ADDRy for some reason, the cleared data (0000h) remains as the ADDRy value. If this ADDRy value is
read into a general register using an A/D scan end interrupt at this point, 0000h will be saved in the general register.
Occurrence of an ADDRy update failure can be determined by simply checking that the read data value is 0000h.
44.3.8 A/D-Converted Value Addition/Average Mode
In A/D-converted value addition mode, the same channel is A/D-converted 2, 3, 4, or 16 consecutive times and the sum
of the converted values is stored in the data register. In A/D-converted value average mode, the same channel is A/D-
converted two or four consecutive times and the mean of the converted values is stored in the data register. The use of the
average of these results can improve the accuracy of A/D conversion, depending on the types of noise components that
are present. This function, however, cannot always guarantee an improvement in A/D conversion accuracy.
The A/D-converted value addition or average mode can be specified when A/D conversion of the channel select analog
input, temperature sensor output, or internal reference voltage is selected.
t
DIAG
t
SCAN
t
CONV
t
ED
DIAG conversion A/D conversion
End
processing
Asynchronous
trigger
(External trigger)
t
D
Waiting
ADST bit
A/D converter