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Table Of Contents

Features
Description
Pin Configuration
Pin Description: RF Part
Pin Description: Microcontroller Part
UHF ASK/FSK Transmitter Block
Features
Description
General Description
Functional Description
- ASK Transmission
- FSK Transmission
- CLK Output
  - Clock Pulse Take Over
  - Output Matching and Power Setting
- Application Circuit
Absolute Maximum Ratings
Thermal Resistance
Electrical Characteristics
Microcontroller Block
Features
Description
Introduction
- Differences between T48C862-R8 and ATAR862 Microconrtollers
Microcontroller Architecture General Description
Components of Microcontroller Core
- Program Memory
- RAM
  - Expression Stack
  - Return Stack
- Registers
- ALU
- I/O Bus
- Instruction Set
- Interrupt Structure
  - Interrupt Processing
  - Interrupt Latency
- Software Interrupts
- Hardware Interrupts
Master Reset
- Power-on Reset and Brown-out Detection
  - Watchdog Reset
  - External Clock Supervisor
Voltage Monitor
- Voltage Monitor Control/Status Register
Clock Generation
- Clock Module
- Oscillator Circuits and External Clock Input Stage
- Clock Management
  - Clock Management Register (CM)
  - System Configuration Register (SC)
Power-down Modes
Peripheral Modules
- Addressing Peripherals
Bi-directional Ports
- Bi-directional Port 1
- Bi-directional Port 2
  - Port 2 Data Register (P2DAT)
  - Port 2 Control Register (P2CR)
- Bi-directional Port 5
  - Port 5 Data Register (P5DAT)
  - Port 5 Control Register (P5CR) Byte Write
- Bi-directional Port 4
  - Port 4 Data Register (P4DAT)
  - Port 4 Control Register (P4CR) Byte Write
- Bi-directional Port 6
  - Port 6 Data Register (P6DAT)
  - Port 6 Control Register (P6CR)
- Universal Timer/Counter/ Communication Module (UTCM)
- Timer 1
- Timer 2
- Timer 2 Modes
- Timer 2 Output Modes
- Timer 2 Output Signals
- Timer 2 Registers
Timer 3
- Features
- Timer/Counter Modes
- Timer 3 Modulator/Demodulator Modes
- Timer 3 Modulator for Carrier Frequency Burst Modulation
- Timer 3 Demodulator for Biphase, Manchester and Pulse-width-modulated Signals
- Timer 3 Registers
- Timer 3 Capture Register
  - Timer 3 CaPture Register (T3CP) Byte Read
- Synchronous Serial Interface (SSI)
- Serial Interface Registers
Combination Modes
- Combination Mode Timer 2 and SSI
- Combination Mode Timer 3 and SSI
- Combination Mode Timer 2 and Timer 3
  - Combination Mode 10: Frequency Measurement or Event Counter with Time Gate
  - Combination Mode 11: Burst Modulation 1
- Combination Mode Timer 2, Timer 3 and SSI
  - Combination Mode 12: Burst Modulation 2
  - Combination Mode 13: FSK Modulation
- Data EEPROM
- Serial Interface
  - Serial Protocol
  - Control Byte Format
- EEPROM
- Initialization the Serial Interface to the EEPROM
Absolute Maximum Ratings
Thermal Resistance
DC Operating Characteristics
AC Characteristics
Crystal Characteristics
Ordering Information
Package Information
Table of Contents

T48C862-R8

4590B–4BMCU–02/03

MCL Bus Protocol The MCL protocol constitutes a simple 2-wire bi-directional communication highway via

which devices can communicate control and data information. Although the MCL proto-

col can support multi-master bus configurations, the SSI in MCL mode is intended for

use purely as a master controller on a single master bus system. So all reference to

multiple bus control and bus contention will be omitted at this point.

All data is packaged into 8-bit telegrams plus a trailing handshaking or acknowledge-bit.

Normally the communication channel is opened with a so-called start condition, which

initializes all devices connected to the bus. This is then followed by a data telegram,

transmitted by the master controller device. This telegram usually contains an 8-bit

address code to activate a single slave device connected onto the I

C bus. Each slave

receives this address and compares it with its own unique address. The addressed

slave device, if ready to receive data, will respond by pulling the SD line low during the

9th clock pulse. This represents a so-called MCL acknowledge. The controller detecting

this affirmative acknowledge then opens a connection to the required slave. Data can

then be passed back and forth by the master controller, each 8-bit telegram being

acknowledged by the respective recipient. The communication is finally closed by the

master device and the slave device put back into standby by applying a stop condition

onto the bus.

Figure 69. MCL Bus Protocol 1

Bus not busy (1) Both data and clock lines remain HIGH.

Start data transfer (2) A HIGH to LOW transition of the SD line while the clock (SC)

is HIGH defines a START condition

Stop data transfer (3) A LOW to HIGH transition of the SD line while the clock (SC)

is HIGH defines a STOP condition.

Data valid (4) The state of the data line represents valid data when,

after START condition, the data line is stable for the

duration of the HIGH period of the clock signal.

Acknowledge All address and data words are serially transmitted to and

from the device in eight-bit words. The receiving device

returns a zero on the data line during the ninth clock cycle to

acknowledge word receipt.

(2)(1) (4) (4) (3) (1)

Start

condition

Data

valid

Data

change

Data

valid

Stop

condition