S9S12G96F0MLH Freescale Semiconductor, S9S12G96F0MLH Datasheet - Page 356

S9S12G96F0MLH

Manufacturer Part Number

S9S12G96F0MLH

Description

16-bit Microcontrollers - MCU 16BIT 96K FLASH

Manufacturer

Freescale Semiconductor

Datasheet

1.S9S12G96F0CLL.pdf (1292 pages)

Specifications of S9S12G96F0MLH

Rohs

yes

Core

S12

Processor Series

MC9S12G

Data Bus Width

16 bit

Maximum Clock Frequency

25 MHz

Program Memory Size

96 KB

Data Ram Size

8192 B

On-chip Adc

Yes

Operating Supply Voltage

3.13 V to 5.5 V

Operating Temperature Range

- 40 C to + 125 C

Package / Case

LQFP-64

Mounting Style

SMD/SMT

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Security (S12XS9SECV2)

memory and EEPROM, another reset into special single chip mode will cause the blank check to succeed

and the options/security byte can be programmed to “unsecured” state via BDM.

While the BDM is executing the blank check, the BDM interface is completely blocked, which means that

all BDM commands are temporarily blocked.

9.1.5

Unsecuring the microcontroller can be done by three different methods:

9.1.5.1

In normal modes (single chip and expanded), security can be temporarily disabled using the backdoor key

access method. This method requires that:

The backdoor key values themselves would not normally be stored within the application data, which

means the application program would have to be designed to receive the backdoor key values from an

external source (e.g. through a serial port).

The backdoor key access method allows debugging of a secured microcontroller without having to erase

the Flash. This is particularly useful for failure analysis.

9.1.6

In normal single chip mode (NS), security can also be disabled by erasing and reprogramming the security

bits within Flash options/security byte to the unsecured value. Because the erase operation will erase the

entire sector from 0xFE00–0xFFFF (0x7F_FE00–0x7F_FFFF), the backdoor key and the interrupt vectors

will also be erased; this method is not recommended for normal single chip mode. The application

software can only erase and program the Flash options/security byte if the Flash sector containing the Flash

options/security byte is not protected (see Flash protection). Thus Flash protection is a useful means of

preventing this method. The microcontroller will enter the unsecured state after the next reset following

the programming of the security bits to the unsecured value.

This method requires that:

358

1. Backdoor key access

2. Reprogramming the security bits

3. Complete memory erase (special modes)

•

The backdoor key at 0xFF00–0xFF07 (= global addresses 0x3_FF00–0x3_FF07) has been

programmed to a valid value.

The KEYEN[1:0] bits within the Flash options/security byte select ‘enabled’.

In single chip mode, the application program programmed into the microcontroller must be

designed to have the capability to write to the backdoor key locations.

Unsecuring the Microcontroller

Reprogramming the Security Bits

Unsecuring the MCU Using the Backdoor Key Access

No word of the backdoor key is allowed to have the value 0x0000 or

0xFFFF.

MC9S12G Family Reference Manual,

NOTE

Rev.1.23

Freescale Semiconductor

S9S12G96F0MLH Freescale Semiconductor, S9S12G96F0MLH Datasheet - Page 356

S9S12G96F0MLH

Specifications of S9S12G96F0MLH

Available stocks

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