Abstract: This inventing is intended to shorten data deletion time of a nonvolatile semiconductor memory such as a flash memory (EEPROM). When deleting data written to a memory cell MC0 among flash memory cells MC0 to MC2 formed on a semiconductor substrate PSUB through a separation region NiSO, a voltage of p type well PWL0 in which the memory cell MC0 is formed is raised to 10V and a voltage of the separation region NiSO is raised to 12V by using a voltage application unit different from a voltage application unit applying a voltage to the p type well PWL0. As a result, parasitic capacitances Ca1and Ca2 generated between p type wells PWL1 and PWL2 in which the unselected memory cells MC1 and MC2 are formed and the separation region NiSO, respectively, and a parasitic capacitance Cb generated between the separation region NiSO and the semiconductor substrate PSUB are charged by the voltage application units.

Abstract: In a verify operation after a write or erase to check whether a memory cell threshold voltage is contained in a predetermined threshold voltage distribution, verify voltage is changed in three stages or more in a direction to mitigate the decision condition. This prevents non-convergence of write and erase operation and can complete the write or erase in a short time.

Abstract: The invention includes a control register (CRG) for providing instructions as to basic operations such as writing, erasing, reading, etc., a boosted voltage attainment detecting circuit for detecting whether a voltage boosted by a booster circuit has reached a desired level, a circuit which counts the time required to apply each of write and erase voltages, and a circuit which detects the completion of the writing or erasing. Respective operations are automatically advanced by simple setting of the operation instructions to the control register. After the completion of the operations, an end flag (FLAG) provided within the control register is set to notify the completion of the writing or erasing.

Abstract: A system with a ferroelectric memory has a low probability of soft error thereby decreasing the possibility of serious damage to the system that might result from soft errors. The ferroelectric memory is provided with an overwrite-inhibited memory block 122 for storing this OS (Operating System) and applications, and an overwrite-free memory block 123 which is a work area. The overwrite-inhibited memory block 122 includes a parity bit storage 125. A process for checking and correcting error performed about one a day. A command for starting the error checking and correcting procedures is triggered by a switch such as power source switch. When an error occurs in the ferroelectric memory 120, it is possible to recover the function of the system.

Abstract: A system with a ferroelectric memory has a low probability of soft error thereby decreasing the possibility of serious damage to the system that might result from soft errors. The ferroelectric memory is provided with an overwrite-inhibited memory block 122 for storing the OS (Operating System) and applications, and an overwrite-free memory block 123 which is a work area. The overwrite-inhibited memory block 122 includes a parity bit storage 125. A process for checking and correcting error performed about once a day. A command for starting the error checking and correcting procedures is triggered by a switch such as power source switch. When an error occurs in the ferroelectric memory 120, it is possible to recover the function of the system.