Posts Tagged ‘extract pld ic heximal’

PostHeaderIcon Extract PLD IC Source Code

Extract PLD IC Source Code from PLD chip memory, crack PLD IC tamper resistance system and disable the security fuse bit, readout the firmware from PLD IC memory;

Extract PLD IC Source Code from PLD chip memory, crack PLD IC tamper resistance system and disable the security fuse bit, readout the firmware from PLD IC memory

Extract PLD IC Source Code from PLD chip memory, crack PLD IC tamper resistance system and disable the security fuse bit, readout the firmware from PLD IC memory

Obviously, in a floating gate memory cell, the floating gate itself cannot be accessed. Its voltage is controlled through capacitive coupling with the external nodes of the device. Often, the floating-gate transistor is modelled by a capacitor equivalent circuit called the capacitor model. In practice, write/erase characteristics for many EEPROM/Flash memories are close to that of a charge/discharge of a capacitor. Meanwhile there are some differences in how the charge/discharge process takes place in real memory cells. There is an initial delay between the time the voltages are applied to the cell, and the charge starting to be removed or injected.

This delay is caused by the need for very high electric fields to be created inside the floating-gate transistor to start the injection or tunnelling process. Some EEPROM cells have been reported to have nonuniformity during the erase operation. As a result, it might take longer to erase a half-charged cell than a fully-charged cell. In addition, an ideal capacitor discharges exponentially: q = q0 e−t. Applied to the floating gate, that would mean that after t=10 the charge is totally removed from the cell.In practice this doesn’t happen, because the  parameters of the cell’s transistor change as the charge is removed from its floating gate. All the above-mentioned problems could seriously affect data remanence in floating-gate memories.

The main difficulty with analysis of the floating-gate memory devices, especially EEPROM and Flash, is the variety of different designs and implementations from many semiconductor manufacturers. There are hundreds of different types of floating-gate transistor, each with its own characteristics and peculiarities. It means that for security applications where data remanence could cause problems, careful testing should be applied to the specific non-volatile memory device used in the system.

PostHeaderIcon Extract PLD IC Firmware

Extract PLD IC Firmware include program of flash memory and data of eeprom memory, PLD IC embedded content can be cloned and copy the code to new PLD chip;

Extract PLD IC Firmware include program of flash memory and data of eeprom memory, PLD IC embedded content can be cloned and copy the code to new PLD chip;

Extract PLD IC Firmware include program of flash memory and data of eeprom memory, PLD IC embedded content can be cloned and copy the code to new PLD chip;

Programmed floating-gate memories cannot store information forever. Various processes (such as field-assisted electron emission and ionic contamination) cause the floating gate to lose the charge, and go faster at higher temperatures. Another failure mode in the very thin tunnel oxides used in Flash memories is programming disturb, where unselected erased cells adjacent to selected cells gain charge when the selected cell is written.

This is not enough to change the cell threshold sufficiently to upset a normal read operation, but could cause problems to the data retention time and should be considered during measurement of the threshold voltage of the cells for data analysis and information recovery. Typical guaranteed data retention time for EPROM, EEPROM and Flash memories are 10, 40 and 100 years respectively.