INDEX

 

T

 

TBTC

 

Time-base Timer Control Register (TBTC)

119

TCCR

 

Capture Control Register (TCCR)

171

TCPH and TCPL

 

Capture Data Registers H and L (TCPH and TCPL)

..........................................................

182

TCR

 

Timer 0 Control Register (TCR0)

173

Timer 1 Control Register (TCR1)

175

Timer Output Control Register (TCR2)

177

TDR

 

Timer 0 Data Register (TDR0)

178

Timer 1 Data Register (TDR1)

180

Theory

 

Theory of Operation for Operating Mode 0,1,2, and 3

..........................................................

305

Time-base Timer

 

Block Diagram of Time-base Timer

118

Notes on Using Time-base Timer

124

Operations of Interval Timer Function

 

(Time-base Timer)

122

Operations of Time-base Timer

122

Oscillation Stabilization Time and Time-base Timer

Interrupts

121

Programming Examples for Time-base Timer

 

..........................................................

125

Register and Vector Table Related to Interrupts from

Time-base Timer

121

Time-base Timer Control Register

 

Time-base Timer Control Register (TBTC)

119

Timer 0 Control Register

 

Timer 0 Control Register (TCR0)

173

Timer 0 Data Register

 

Timer 0 Data Register (TDR0)

178

Timer 1 Control Register

 

Timer 1 Control Register (TCR1)

175

Timer 1 Data Register

 

Timer 1 Data Register (TDR1)

180

Timer Output Control Register

 

Timer Output Control Register (TCR2)

177

tINST

 

Instruction Cycle (tINST)

57

Transfer

 

Transfer Instructions

392

Transfer Clock Rate

 

Choice of the Transfer Clock Rate

281

Transferred Data Format

 

Transferred Data Format

304

Transition

 

Diagram for State Transition in Standby Mode

 

............................................................

68

Transition to Standby Mode and Interrupt

70

Transmission

 

Transmission Interrupt

303

Transmission Operations

 

Transmission Operations in Operating Mode is

 

0,1,2,or 3

306

U

 

UART

 

Block Diagram of the UART-relating Pins

 

.........................................................

288

Block Diagram of UART

284

Functions of UART

280

Program Example for UART

311

UART Relating Pins

287

UART-relating Registers

289

UART Interrupt Related Registers

 

UART Interrupt Related Registers and Vector Table

Addresses

303

UART-relating Registers

 

UART-relating Registers

289

UPC

 

Clock Divider Selection Register (UPC)

299

V

 

Vector Table

 

8-bit Serial I/O Interrupt Register and Vector

 

Table

324

Register and Vector Table Related to 8/16-bit Capture

Timer/Counter of Interrupts

184

Register and Vector Table Related to Interrupts from

Time-base Timer

121

Register and Vector Table Related to the Interrupt of

the A/D Converter

272

Register and Vector Table Related to the Interrupts of

an 8-bit PWM Timer

147

Register Associated with Interrupt Generation by

External Interrupt Circuit 1 and Vector

 

Table

238

Register Associated with Interrupt Generation by

External Interrupt Circuit 2 and Vector

 

Table

253

UART Interrupt Related Registers and Vector Table

Addresses

303

Vector Table Area

 

Vector Table Area

 

(Address: FFC0H to FFFFH)

24

W

 

Watchdog Control Register

 

Watchdog Control Register (WDTC)

130

Watchdog Timer

 

Block Diagram of Watchdog Timer

129

Notes on Using Watchdog Timer

132

416

Page 432
Image 432
Fujitsu MB89202, F202RA manual Tbtc, Tccr, Tcr, Tdr, Upc

F202RA, MB89202 specifications

The Fujitsu MB89202 and F202RA microcontrollers are part of the 16-bit microcontroller family, renowned for their robust performance and versatility in a variety of embedded system applications. These devices are tailored for high-efficiency operation across diverse industries, including automotive, consumer electronics, and industrial automation.

One of the main features of the MB89202 is its powerful CPU core, which operates at a clock speed of up to 20 MHz. This enables the microcontroller to perform complex calculations and consumer-grade applications seamlessly. The architecture is designed to handle multiple tasks effectively, making it suitable for real-time operations.

Memory capacity is a vital characteristic of the MB89202, featuring on-chip RAM and ROM configurations. The microcontroller can accommodate different memory variants, providing developers with flexibility in memory allocation based on their application requirements. This adaptability facilitates applications ranging from simple control systems to complex data processing tasks.

The F202RA variant extends the capabilities of the MB89202 by integrating advanced peripheral functions. It includes built-in timers, A/D converters, and serial communication interfaces, which are essential for interfacing with other hardware components or sensors. The availability of these peripherals reduces the need for additional external circuits, thus contributing to a more compact and cost-effective design.

In terms of power management, the MB89202 series employs advanced power-saving technologies. The microcontroller offers various low-power modes, enabling devices to conserve energy during idle times, making it highly suitable for battery-operated applications. This characteristic not only enhances the efficiency of devices but also extends their operational lifespan.

Moreover, the Fujitsu MB89202 series incorporates robust protection features, including watchdog timers and failure detection mechanisms. These safety features ensure reliable operation in critical systems, making them a preferred choice in applications where failure is not an option.

The MB89202 and F202RA microcontrollers also support a range of development tools and environments, including integrated development environments (IDEs) and software libraries, which facilitate rapid application development. With these tools, developers can efficiently prototype, debug, and optimize their applications.

In summary, the Fujitsu MB89202 and F202RA microcontrollers stand out with their efficient performance, extensive memory options, integrated peripherals, and power-saving capabilities, making them ideal for a wide array of embedded applications. Their reliability and robustness further enhance their attractiveness for designers seeking advanced microcontroller solutions.