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Файл:ATtiny104_Datasheet.pdf
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- •Introduction
- •Feature
- •Table of Contents
- •1. Description
- •2. Configuration Summary
- •3. Ordering Information
- •4. Block Diagram
- •5. Pin Configurations
- •5.1. Pin Descriptions
- •5.1.3. Port A (PA[7:0])
- •5.1.4. Port B (PB[3:0])
- •5.1.5. RESET
- •6. I/O Multiplexing
- •7. General Information
- •7.1. Resources
- •7.2. Data Retention
- •7.3. About Code Examples
- •8. AVR CPU Core
- •8.1. Overview
- •8.2. Features
- •8.3. Block Diagram
- •8.4. ALU – Arithmetic Logic Unit
- •8.5. Status Register
- •8.6. General Purpose Register File
- •8.8. Stack Pointer
- •8.10. Instruction Execution Timing
- •8.11. Reset and Interrupt Handling
- •8.11.1. Interrupt Response Time
- •8.12. Register Description
- •8.12.1. Configuration Change Protection Register
- •8.12.2. Stack Pointer Register Low and High byte
- •8.12.3. Status Register
- •9. AVR Memories
- •9.1. Overview
- •9.2. Features
- •9.4. SRAM Data Memory
- •9.4.1. Data Memory Access Times
- •9.5. I/O Memory
- •10. Clock System
- •10.1. Overview
- •10.2. Clock Distribution
- •10.3. Clock Subsystems
- •10.4. Clock Sources
- •10.4.1. Calibrated Internal 8MHz Oscillator
- •10.4.2. External Clock
- •10.4.3. Internal 128kHz Oscillator
- •10.4.4. Switching Clock Source
- •10.4.5. Default Clock Source
- •10.5. System Clock Prescaler
- •10.5.1. Switching Prescaler Setting
- •10.6. Starting
- •10.6.1. Starting from Reset
- •10.6.2. Starting from Power-Down Mode
- •10.6.3. Starting from Idle / ADC Noise Reduction / Standby Mode
- •10.7. Register Description
- •10.7.1. Clock Main Settings Register
- •10.7.2. Oscillator Calibration Register
- •10.7.3. Clock Prescaler Register
- •11. Power Management and Sleep Modes
- •11.1. Overview
- •11.2. Features
- •11.3. Sleep Modes
- •11.3.1. Idle Mode
- •11.3.2. ADC Noise Reduction Mode
- •11.3.4. Standby Mode
- •11.4. Power Reduction Register
- •11.5. Minimizing Power Consumption
- •11.5.1. Analog Comparator
- •11.5.2. Analog to Digital Converter
- •11.5.3. Internal Voltage Reference
- •11.5.4. Watchdog Timer
- •11.5.5. Port Pins
- •11.6. Register Description
- •11.6.1. Sleep Mode Control Register
- •11.6.2. Power Reduction Register
- •12. SCRST - System Control and Reset
- •12.1. Overview
- •12.2. Features
- •12.3. Resetting the AVR
- •12.4. Reset Sources
- •12.4.3. External Reset
- •12.4.4. Watchdog System Reset
- •12.5. Watchdog Timer
- •12.5.1. Overview
- •12.5.2. Procedure for Changing the Watchdog Timer Configuration
- •12.5.2.1. Safety Level 1
- •12.5.2.2. Safety Level 2
- •12.5.3. Code Examples
- •12.6. Register Description
- •12.6.1. Watchdog Timer Control Register
- •12.6.2. VCC Level Monitoring Control and Status register
- •12.6.3. Reset Flag Register
- •13. Interrupts
- •13.1. Overview
- •13.2. Interrupt Vectors
- •13.3. External Interrupts
- •13.3.1. Low Level Interrupt
- •13.3.2. Pin Change Interrupt Timing
- •13.4. Register Description
- •13.4.1. External Interrupt Control Register A
- •13.4.2. External Interrupt Mask Register
- •13.4.3. External Interrupt Flag Register
- •13.4.4. Pin Change Interrupt Control Register
- •13.4.5. Pin Change Interrupt Flag Register
- •13.4.6. Pin Change Mask Register 0
- •13.4.7. Pin Change Mask Register 1
- •14. I/O-Ports
- •14.1. Overview
- •14.2. Features
- •14.3. I/O Pin Equivalent Schematic
- •14.4. Ports as General Digital I/O
- •14.4.1. Configuring the Pin
- •14.4.2. Toggling the Pin
- •14.4.4. Reading the Pin Value
- •14.4.5. Digital Input Enable and Sleep Modes
- •14.4.6. Unconnected Pins
- •14.4.7. Program Example
- •14.4.8. Alternate Port Functions
- •14.4.8.1. Alternate Functions of Port A
- •14.4.8.2. Alternate Functions of Port B
- •14.5. Register Description
- •14.5.1. Port A Input Pins Address
- •14.5.2. Port A Data Direction Register
- •14.5.3. Port A Data Register
- •14.5.5. Port B Input Pins Address
- •14.5.6. Port B Data Direction Register
- •14.5.7. Port B Data Register
- •14.5.9. Port Control Register
- •15. USART - Universal Synchronous Asynchronous Receiver Transceiver
- •15.1. Overview
- •15.2. Features
- •15.3. Block Diagram
- •15.4. Clock Generation
- •15.4.1. Internal Clock Generation – The Baud Rate Generator
- •15.4.2. Double Speed Operation (U2X0)
- •15.4.3. External Clock
- •15.4.4. Synchronous Clock Operation
- •15.5. Frame Formats
- •15.5.1. Parity Bit Calculation
- •15.6. USART Initialization
- •15.7. Data Transmission – The USART Transmitter
- •15.7.1. Sending Frames with 5 to 8 Data Bits
- •15.7.2. Sending Frames with 9 Data Bit
- •15.7.3. Transmitter Flags and Interrupts
- •15.7.4. Parity Generator
- •15.7.5. Disabling the Transmitter
- •15.8. Data Reception – The USART Receiver
- •15.8.1. Receiving Frames with 5 to 8 Data Bits
- •15.8.2. Receiving Frames with 9 Data Bits
- •15.8.3. Receive Compete Flag and Interrupt
- •15.8.4. Receiver Error Flags
- •15.8.5. Parity Checker
- •15.8.6. Disabling the Receiver
- •15.8.7. Flushing the Receive Buffer
- •15.9. Asynchronous Data Reception
- •15.9.1. Asynchronous Clock Recovery
- •15.9.2. Asynchronous Data Recovery
- •15.9.3. Asynchronous Operational Range
- •15.9.4. Start Frame Detection
- •15.10. Multi-Processor Communication Mode
- •15.10.1. Using MPCMn
- •15.11. Examples of Baud Rate Setting
- •15.12. Register Description
- •15.12.1. USART I/O Data Register 0
- •15.12.2. USART Control and Status Register 0 A
- •15.12.3. USART Control and Status Register 0 B
- •15.12.4. USART Control and Status Register 0 C
- •15.12.5. USART Control and Status Register 0 D
- •15.12.6. USART Baud Rate 0 Register Low and High byte
- •16. USARTSPI - USART in SPI Mode
- •16.1. Overview
- •16.2. Features
- •16.3. Clock Generation
- •16.4. SPI Data Modes and Timing
- •16.5. Frame Formats
- •16.5.1. USART MSPIM Initialization
- •16.6. Data Transfer
- •16.6.1. Transmitter and Receiver Flags and Interrupts
- •16.6.2. Disabling the Transmitter or Receiver
- •16.7. AVR USART MSPIM vs. AVR SPI
- •16.8. Register Description
- •17.1. Overview
- •17.2. Features
- •17.3. Block Diagram
- •17.4. Definitions
- •17.5. Registers
- •17.6.1. Reusing the Temporary High Byte Register
- •17.7. Timer/Counter Clock Sources
- •17.7.1. Internal Clock Source - Prescaler
- •17.7.2. Prescaler Reset
- •17.7.3. External Clock Source
- •17.8. Counter Unit
- •17.9. Input Capture Unit
- •17.9.1. Input Capture Trigger Source
- •17.9.2. Noise Canceler
- •17.9.3. Using the Input Capture Unit
- •17.10. Output Compare Units
- •17.10.1. Force Output Compare
- •17.10.2. Compare Match Blocking by TCNT0 Write
- •17.10.3. Using the Output Compare Unit
- •17.11. Compare Match Output Unit
- •17.11.1. Compare Output Mode and Waveform Generation
- •17.12. Modes of Operation
- •17.12.1. Normal Mode
- •17.12.2. Clear Timer on Compare Match (CTC) Mode
- •17.12.3. Fast PWM Mode
- •17.12.4. Phase Correct PWM Mode
- •17.12.5. Phase and Frequency Correct PWM Mode
- •17.13. Timer/Counter Timing Diagrams
- •17.14. Register Description
- •17.14.1. Timer/Counter0 Control Register A
- •17.14.2. Timer/Counter0 Control Register B
- •17.14.3. Timer/Counter0 Control Register C
- •17.14.4. Timer/Counter 0 Low and High byte
- •17.14.5. Output Comparte Register A 0 Low and High byte
- •17.14.6. Output Comparte Register B 0 Low and High byte
- •17.14.7. Input Capture Register 0 Low and High byte
- •17.14.8. Timer/Counter0 Interrupt Mask Register
- •17.14.9. Timer/Counter0 Interrupt Flag Register
- •17.14.10. General Timer/Counter Control Register
- •18. AC - Analog Comparator
- •18.1. Overview
- •18.2. Features
- •18.3. Block Diagram
- •18.4. Register Description
- •18.4.1. Analog Comparator Control and Status Register
- •18.4.2. Analog Comparator Control and Status Register 0
- •18.4.3. Digital Input Disable Register 0
- •19. ADC - Analog to Digital Converter
- •19.1. Overview
- •19.2. Features
- •19.3. Block Diagram
- •19.4. Operation
- •19.5. Starting a Conversion
- •19.6. Prescaling and Conversion Timing
- •19.7. Changing Channel or Reference Selection
- •19.8. ADC Input Channels
- •19.9. ADC Voltage Reference
- •19.10. ADC Noise Canceler
- •19.11. Analog Input Circuitry
- •19.12. Analog Noise Canceling Techniques
- •19.13. ADC Accuracy Definitions
- •19.14. ADC Conversion Result
- •19.15. Register Description
- •19.15.1. ADC Multiplexer Selection Register
- •19.15.2. ADC Control and Status Register A
- •19.15.3. ADC Control and Status Register B
- •19.15.4. ADC Data Register Low and High Byte (ADLAR=0)
- •19.15.5. ADC Data Register Low and High Byte (ADLAR=1)
- •19.15.6. Digital Input Disable Register 0
- •20.1. Overview
- •20.2. Features
- •20.3.2. Flash Memory
- •20.3.3. Configuration Section
- •20.3.3.1. Latching of Configuration Bits
- •20.3.4. Signature Section
- •20.3.4.1. Signature Row Summary
- •20.3.4.1.1. Device ID n
- •20.3.4.1.2. Serial Number Byte n
- •20.3.5. Calibration Section
- •20.4. Accessing the NVM
- •20.4.1. Addressing the Flash
- •20.4.2. Reading the Flash
- •20.4.3. Programming the Flash
- •20.4.3.1. Chip Erase
- •20.4.3.2. Erasing the Code Section
- •20.4.3.3. Writing a Code Word
- •20.4.3.4. Erasing the Configuration Section
- •20.4.3.5. Writing a Configuration Word
- •20.4.4. Reading NVM Lock Bits
- •20.4.5. Writing NVM Lock Bits
- •20.5. Self programming
- •20.6. External Programming
- •20.6.1. Entering External Programming Mode
- •20.6.2. Exiting External Programming Mode
- •20.7. Register Description
- •21.1. Overview
- •21.2. Features
- •21.3. Block Diagram
- •21.4. Physical Layer of Tiny Programming Interface
- •21.4.1. Enabling
- •21.4.2. Disabling
- •21.4.3. Frame Format
- •21.4.4. Parity Bit Calculation
- •21.4.5. Supported Characters
- •21.4.6. Operation
- •21.4.7. Serial Data Reception
- •21.4.8. Serial Data Transmission
- •21.4.9. Collision Detection Exception
- •21.4.10. Direction Change
- •21.4.11. Access Layer of Tiny Programming Interface
- •21.4.11.1. Message format
- •21.4.11.2. Exception Handling and Synchronisation
- •21.5. Instruction Set
- •21.5.1. SLD - Serial LoaD from data space using indirect addressing
- •21.5.2. SST - Serial STore to data space using indirect addressing
- •21.5.3. SSTPR - Serial STore to Pointer Register
- •21.5.4. SIN - Serial IN from i/o space using direct addressing
- •21.5.5. SOUT - Serial OUT to i/o space using direct addressing
- •21.5.6. SLDCS - Serial LoaD data from Control and Status space using direct addressing
- •21.5.7. SSTCS - Serial STore data to Control and Status space using direct addressing
- •21.5.8. SKEY - Serial KEY signaling
- •21.7. Control and Status Space Register Descriptions
- •21.7.1. Tiny Programming Interface Identification Register
- •21.7.2. Tiny Programming Interface Physical Layer Control Register
- •21.7.3. Tiny Programming Interface Status Register
- •22. Electrical Characteristics
- •22.1. Absolute Maximum Ratings*
- •22.2. DC Characteristics
- •22.3. Speed
- •22.4. Clock Characteristics
- •22.4.1. Accuracy of Calibrated Internal Oscillator
- •22.4.2. External Clock Drive
- •22.5. System and Reset Characteristics
- •22.6. Analog Comparator Characteristics
- •22.7. ADC Characteristics
- •22.8. Serial Programming Characteristics
- •23. Typical Characteristics
- •23.1. Active Supply Current
- •23.2. Idle Supply Current
- •23.3. Supply Current of I/O Modules
- •23.5. Pin Driver Strength
- •23.6. Pin Threshold and Hysteresis
- •23.7. Analog Comparator Offset
- •23.9. Internal Oscillator Speed
- •23.10. VLM Thresholds
- •23.11. Current Consumption of Peripheral Units
- •23.12. Current Consumption in Reset and Reset Pulsewidth
- •24. Register Summary
- •24.1. Note
- •25. Instruction Set Summary
- •26. Packaging Information
- •27. Errata
- •27.1. ATtiny102
- •27.2. ATtiny104
- •28. Datasheet Revision History
16.USARTSPI - USART in SPI Mode
16.1.Overview
The Universal Synchronous and Asynchronous serial Receiver and Transmitter (USART) can be set to a master SPI compliant mode of operation.
Setting both UMSELn[1:0] bits to one enables the USART in MSPIM logic. In this mode of operation the SPI master control logic takes direct control over the USART resources. These resources include the transmitter and receiver shift register and buffers, and the baud rate generator. The parity generator and checker, the data and clock recovery logic, and the RX and TX control logic is disabled. The USART RX and TX control logic is replaced by a common SPI transfer control logic. However, the pin control logic and interrupt generation logic is identical in both modes of operation.
The I/O register locations are the same in both modes. However, some of the functionality of the control registers changes when using MSPIM.
16.2.Features
•Full Duplex, Three-wire Synchronous Data Transfer
•Master Operation
•Supports all four SPI Modes of Operation (Mode 0, 1, 2, and 3)
•LSB First or MSB First Data Transfer (Configurable Data Order)
•Queued Operation (Double Buffered)
•High Resolution Baud Rate Generator
•High Speed Operation (fXCKmax = fCK/2)
•Flexible Interrupt Generation
16.3.Clock Generation
The Clock Generation logic generates the base clock for the Transmitter and Receiver. For USART MSPIM mode of operation only internal clock generation (i.e. master operation) is supported. The Data Direction Register for the XCKn pin (DDR_XCKn) must therefore be set to one (i.e. as output) for the USART in MSPIM to operate correctly. Preferably the DDR_XCKn should be set up before the USART in MSPIM is enabled (i.e. TXENn and RXENn bit set to one).
The internal clock generation used in MSPIM mode is identical to the USART synchronous master mode. The table below contains the equations for calculating the baud rate or UBRRn setting for Synchronous Master Mode.
Table 16-1. Equations for Calculating Baud Rate Register Setting
Operating Mode |
Equation for Calculating Baud |
Equation for Calculating UBRRn |
||||||
|
Rate(1) |
|
|
|
Value |
|
|
|
mode |
BAUD = 2 |
OSC |
+ 1 |
|
|
= 2BAUD |
1 |
|
|
|
|
|
|
OSC |
|
||
Synchronous Master |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Note: 1. The baud rate is defined to be the transfer rate in bit per second (bps)
Atmel ATtiny102 / ATtiny104 [DATASHEET] 119
Atmel-42505D-ATtiny102-ATtiny104_Datasheet_Complete-10/2016
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