ST10F276-6Q3 STMicroelectronics, ST10F276-6Q3 Datasheet - Page 47

ST10F276-6Q3

Manufacturer Part Number

ST10F276-6Q3

Description

MCU 16BIT 832K FLASH 144-PQFP

Manufacturer

STMicroelectronics

Series

ST10r

Datasheet

1.ST10F276-4TR3.pdf (231 pages)

Specifications of ST10F276-6Q3

Core Processor

ST10

Core Size

16-Bit

Speed

64MHz

Connectivity

ASC, CAN, EBI/EMI, I²C, SSC, UART/USART

Peripherals

POR, PWM, WDT

Number Of I /o

111

Program Memory Size

832KB (832K x 8)

Program Memory Type

FLASH

Ram Size

68K x 8

Voltage - Supply (vcc/vdd)

4.5 V ~ 5.5 V

Data Converters

A/D 24x10b

Oscillator Type

Internal

Operating Temperature

-40°C ~ 125°C

Package / Case

144-MQFP, 144-PQFP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Eeprom Size

Current page: 47 of 231
Download datasheet (5Mb)

ST10F276E

5.2

5.2.1

Table 28.

Standard bootstrap loader

The built-in bootstrap loader of the ST10F276E provides a mechanism to load the startup

program, which is executed after reset, via the serial interface. In this case no external

(ROM) memory or an internal ROM is required for the initialization code starting at location

00’0000

transfer data via the serial interface into an external RAM using a second level loader

routine. ROM memory (internal or external) is not necessary. However, it may be used to

provide lookup tables or may provide “core-code”, that is, a set of general purpose

subroutines, such as for I/O operations, number crunching or system initialization.

The Bootstrap Loader can load

●

The BSL mechanism may be used for standard system start-up as well as for only special

occasions like system maintenance (firmware update) or end-of-line programming or

testing.

Entering the standard bootstrap loader

As with the old ST10 bootstrap mode, the ST10F276E enters BSL mode if pin P0L.4 is

sampled low at the end of a hardware reset. In this case, the built-in bootstrap loader is

activated independently of the selected bus mode. The bootstrap loader code is stored in a

special Test-Flash; no part of the standard Flash memory area is required for this.

After entering BSL mode and the respective initialization, the ST10F276E scans the RxD0

line and the CAN1_RxD line to receive either a valid dominant bit from the CAN interface or

a start condition from the UART line.

Start condition on UART RxD: The ST10F276E starts the standard bootstrap loader. This

bootstrap loader is identical to other ST10 devices (Examples: ST10F269, ST10F168). See

Section 5.3

Valid dominant bit on CAN1 RxD: The ST10F276E starts bootstrapping via CAN1; the

bootstrapping method is new and is described in

flow of the new bootstrap loader. It clearly illustrates how the new functionalities are

implemented:

●

P0.5

the complete application software into ROMless systems,

temporary software into complete systems for testing or calibration,

a programming routine for Flash devices.

UART: UART has priority over CAN after a falling edge on CAN1_RxD until the first

valid rising edge on CAN1_RxD;

CAN: Pulses on CAN1_RxD shorter than 20*CPU-cycles are filtered.

. The bootstrap loader moves code/data into the IRAM but it is also possible to

for details.

ST10F276E boot mode selection

P0.4

User mode: User Flash mapped at 00’0000h

Standard bootstrap loader: User Flash mapped from 00’0000h; code fetches

redirected to Test-Flash at 00’0000h

Alternate boot mode: Flash mapping depends on signatures integrity check

Reserved

Section

ST10 decoding

5.4.

Figure 5

shows the program

Bootstrap loader

47/231

ST10F276-6Q3 STMicroelectronics, ST10F276-6Q3 Datasheet - Page 47

ST10F276-6Q3

Specifications of ST10F276-6Q3

Related parts for ST10F276-6Q3