Abstract: Provided are a method for determining a prediction direction, a decoder and a computer storage medium. The method is implemented by a decoder. The method includes that: a Direct Mode (DM) in a chroma intra prediction mode of a block to be decoded is acquired (S101); and an index number of a prediction direction in a DM derived mode is determined based on an offset N and an index number M of a prediction direction in the DM to determine the DM derived mode (S102).

Abstract: A method for decoding a picture, a method for encoding a picture, an encoder, and a decoder are provided. The method for encoding a picture includes (i) determining a width and a height of a coding block in the picture; (ii) if the width and the height are equal to N, where N is a positive integer power of 2, determining a matrix-based intra prediction (MIP) size identifier indicating that an MIP prediction size equal to N; (iii) deriving a group of reference samples of the coding block; and (iv) deriving an MIP prediction of the coding block based on the group of reference samples and an MIP matrix corresponding to the MIP size identifier.

Abstract: Provided are a method for determining a prediction direction, a decoder and a computer storage medium. The method is implemented by a decoder. The method includes that: a Direct Mode (DM) in a chroma intra prediction mode of a block to be decoded is acquired (S101); and an index number of a prediction direction in a DM derived mode is determined based on an offset N and an index number M of a prediction direction in the DM to determine the DM derived mode (S102).

Abstract: Provided in implementations of the present application are a filtering method and apparatus, and a computer storage medium; the method comprises: acquiring pixel information to be filtered; determining edge information; and inputting the sample information to be filtered and the edge information into a neural network-based filter so as to output filtered pixels, the filter being obtained by an online filtering part combined with an offline filtering part.

Abstract: A method and memory for stressing a plurality of non-volatile memory cells is provided. The method includes entering a memory cell stressing mode and providing one or more erase stress pulses to the plurality of non-volatile memory cells; determining that a threshold voltage of at least a subset of the plurality of non-volatile memory cells has a first relationship that is either greater than or less than a first predetermined voltage; providing one or more program stress pulses to the plurality of memory cells; and determining that the threshold voltage of at least a subset of the plurality of memory cells has a second relationship to a second predetermined voltage that is different than the first relationship.

Abstract: A method and memory for stressing a plurality of non-volatile memory cells is provided. The method includes entering a memory cell stressing mode and providing one or more erase stress pulses to the plurality of non-volatile memory cells; determining that a threshold voltage of at least a subset of the plurality of non-volatile memory cells has a first relationship that is either greater than or less than a first predetermined voltage; providing one or more program stress pulses to the plurality of memory cells; and determining that the threshold voltage of at least a subset of the plurality of memory cells has a second relationship to a second predetermined voltage that is different than the first relationship.

Abstract: Methods and systems are disclosed for extended erase protection for non-volatile memory (NVM) cells during embedded erase operations for NVM systems. The embodiments described herein utilize an additional threshold voltage (Vt) check after soft programming operation within an embedded erase operation completes to provide extended erase protection of NVM cells. In particular, the threshold voltages for NVM cells are compared against a threshold voltage (Vt) check voltage (VCHK) level and an additional embedded erase cycle is performed if any NVM cells are found to exceed the threshold voltage (Vt) check voltage (VCHK) level. The threshold voltage (Vt) check voltage (VCHK) level can be, for example, a voltage level that is slightly higher than an erase verify voltage (VEV) level and lower than read voltage level (VR).

Abstract: A charging apparatus connectable to a telephone includes: a base (101), a supply voltage stabilizing device (102), a line coupler device (103) and a charging port (104, 105). The supply voltage stabilizing device and the line coupler device are both fixedly installed on the base; an input port of the supply voltage stabilizing circuit is connected to a supply power (110), the supply voltage stabilizing device is respectively connected to the input port of the line coupler device and the charging port through different output ports; another input port of the line coupler device is connected to a telephone line (120), an output port of the line coupler device is connected to a fixed telephone (130); the charging port comprises a USB port (104) and a charging cable (105); an electrical device is connected to the charging apparatus through a corresponding charging port. Functions for powering a fixed telephone and charging for several electrical products at the same time are integrated in the charging apparatus.

Abstract: A method of soft programming a non-volatile memory (NVM) array includes determining a first number based on a temperature of the NVM array and applying the first number of soft program pulses to a section of the NVM array. A first soft program verify of the section of the NVM array is then performed for a first time after completing the applying the first number of soft program pulses.

Abstract: Methods and systems are disclosed for adjusting read/verify bias conditions for non-volatile memory (NVM) cells to improve performance and product lifetime of NVM systems. System embodiments include integrated NVM systems having a NVM controller, a bias voltage generator, and an NVM cell array. Further, the NVM systems can store performance degradation information and read/verify bias condition information within storage circuitry. The disclosed embodiments adjust read/verify bias conditions for the NVM cells based upon performance degradation determinations, for example, temperature-based performance degradation determinations.

Abstract: A method includes an erase of a plurality of blocks of memory cells in which the memory cells within a block are simultaneously erased. The erase of each block of the plurality of blocks is performed using an erase pulse applied multiple times. The erase pulse is applied to the plurality of blocks in parallel. An erase verify is performed after each application of the erase pulse. After a number applications of the erase pulse, it is determined if a condition comprising one of a group consisting of any memory cell has been more erased than a first predetermined amount and any memory cell has been erased less than a second predetermined amount has been met. If the condition has been met, erasing is continued by applying the erase pulse to the block having the memory cell with the condition independently of the other blocks of the plurality of blocks.

Abstract: A non-volatile memory built-in self-trim mechanism is provided by which product reliability can be improved by minimizing drift of reference current used for accessing the non-volatile memory and for performing initial trimming of the reference current. Embodiments perform these tasks by using an analog-to-digital converter to provide a digital representation of the reference current (Iref) and then comparing that digital representation to a stored target range value for Iref and then adjusting a source of Iref accordingly. For a reference current generated by a NVM reference bitcell, program or erase pulses are applied to the reference cell as part of the trimming procedure. For a reference current generated by a bandgap-based circuit, the comparison results can be used to adjust the reference current circuit. In addition, environmental factors, such as temperature, can be used to adjust the measured value for the reference current or the target range value.

Abstract: Methods and systems are disclosed for adaptive erase recovery of non-volatile memory (NVM) cells within NVM systems. The adaptive erase recovery embodiments adaptively adjust the erase recovery discharge rate and/or discharge time based upon the size of NVM block(s) being erased and operating temperature. In one example embodiment, the erase recovery discharge rate is adjusted by adjusting the number of discharge transistors enabled within the discharge circuitry, thereby adjusting the discharge current for erase recovery. A lookup table is used to store erase recovery discharge rates and/or discharge times associated with NVM block sizes to be recovered and/or operating temperature. By adaptively controlling erase recovery discharge rates and/or times, the disclosed embodiments improve overall erase performance for a wide range of NVM block sizes while avoiding possible damage to high voltage circuitry within the NVM system.

Abstract: A method includes an erase of a plurality of blocks of memory cells in which the memory cells within a block are simultaneously erased. The erase of each block of the plurality of blocks is performed using an erase pulse applied multiple times. The erase pulse is applied to the plurality of blocks in parallel. An erase verify is performed after each application of the erase pulse. After a number applications of the erase pulse, it is determined if a condition comprising one of a group consisting of any memory cell has been more erased than a first predetermined amount and any memory cell has been erased less than a second predetermined amount has been met. If the condition has been met, erasing is continued by applying the erase pulse to the block having the memory cell with the condition independently of the other blocks of the plurality of blocks.

Abstract: A sense amplifier is configured to sense a current from a selected bit cell of a non-volatile memory array and compare the sensed current to a reference current to determine a logic state stored in the bit cell. A controller is configured to perform a program/erase operation on at least a portion of the memory array to change a logic state of at least one bit cell of the portion of the memory array; determine a number of program/erase pulses applied to the at least one bit cell during the program/erase operation to achieve the change in logic state; and when the number of program/erase pulses exceeds a pulse count threshold, adjust the reference current of the sense amplifier for a subsequent program/erase operation.

Abstract: A sense amplifier is configured to sense a current from a selected bit cell of a non-volatile memory array and compare the sensed current to a reference current to determine a logic state stored in the bit cell. A controller is configured to perform a program/erase operation on at least a portion of the memory array to change a logic state of at least one bit cell of the portion of the memory array; determine a number of program/erase pulses applied to the at least one bit cell during the program/erase operation to achieve the change in logic state; and when the number of program/erase pulses exceeds a pulse count threshold, adjust the reference current of the sense amplifier for a subsequent program/erase operation.

Abstract: Methods and systems are disclosed for dynamic healing of non-volatile memory (NVM) cells within NVM systems. The dynamic healing embodiments described herein relax damage within tunnel dielectric layers for NVM cells that occurs over time from charges (e.g., holes and/or electrons) becoming trapped within these tunnel dielectric layers. NVM operations with respect to which dynamic healing processes can be applied include, for example, erase operations, program operations, and read operations. For example, dynamic healing can be applied where performance for the NVM system degrades beyond a selected performance level for an NVM operation, such as elevated erase/program pulse counts for erase/program operations and bit errors for read operations. A variety of healing techniques can be applied, such as drain stress processes, gate stress processes, and/or other desired healing techniques.

Abstract: Methods and systems are disclosed for extended erase protection for non-volatile memory (NVM) cells during embedded erase operations for NVM systems. The embodiments described herein utilize an additional threshold voltage (Vt) check after soft programming operation within an embedded erase operation completes to provide extended erase protection of NVM cells. In particular, the threshold voltages for NVM cells are compared against a threshold voltage (Vt) check voltage (VCHK) level and an additional embedded erase cycle is performed if any NVM cells are found to exceed the threshold voltage (Vt) check voltage (VCHK) level. The threshold voltage (Vt) check voltage (VCHK) level can be, for example, a voltage level that is slightly higher than an erase verify voltage (VEV) level and lower than read voltage level (VR).

Abstract: A semiconductor device comprises an array of memory cells. Each of the memory cells includes a tunnel dielectric, a well region including a first current electrode and a second current electrode, and a control gate. The first and second current electrodes are adjacent one side of the tunnel dielectric and the control gate is adjacent another side of the tunnel dielectric. A controller is coupled to the memory cells. The controller includes logic to determine when to perform a healing process in the tunnel dielectric of the memory cells, and to apply a first voltage to the first current electrode of the memory cells during the healing process to remove trapped electrons and holes from the tunnel dielectric.

Abstract: Methods and systems are disclosed for adaptive erase recovery of non-volatile memory (NVM) cells within NVM systems. The adaptive erase recovery embodiments adaptively adjust the erase recovery discharge rate and/or discharge time based upon the size of NVM block(s) being erased and operating temperature. In one example embodiment, the erase recovery discharge rate is adjusted by adjusting the number of discharge transistors enabled within the discharge circuitry, thereby adjusting the discharge current for erase recovery. A lookup table is used to store erase recovery discharge rates and/or discharge times associated with NVM block sizes to be recovered and/or operating temperature. By adaptively controlling erase recovery discharge rates and/or times, the disclosed embodiments improve overall erase performance for a wide range of NVM block sizes while avoiding possible damage to high voltage circuitry within the NVM system.