Patent application number | Description | Published |
20090040842 | Enhanced write abort mechanism for non-volatile memory - In a non-volatile memory (NVM) device having a controller and a non-volatile memory array controlled by the controller a voltage supervisor circuit monitors an output of a voltage supply powering the NVM device. The voltage supervisor circuit may be part of the NVM device or coupled to it. The voltage supervisor circuit is configured to assert a “low-voltage” signal responsive to detecting the output of the voltage supply powering the NVM device dropping below a predetermined value. The controller is configured to write data into the memory array while the “low-voltage” signal is deasserted and to suspend writing data while the “low-voltage” signal is asserted. In response to assertion of the “low-voltage” signal, the controller completes a write cycle/program operation, if pending, and prevents any additional write cycles/program operation(s) during assertion of the “low-voltage” signal. | 02-12-2009 |
20090040843 | Enhanced write abort mechanism for non-volatile memory - In a non-volatile memory (NVM) device having a controller and a non-volatile memory array controlled by the controller a voltage supervisor circuit monitors an output of a voltage supply powering the NVM device. The voltage supervisor circuit may be part of the NVM device or coupled to it. The voltage supervisor circuit is configured to assert a “low-voltage” signal responsive to detecting the output of the voltage supply powering the NVM device dropping below a predetermined value. The controller is configured to write data into the memory array while the “low-voltage” signal is deasserted and to suspend writing data while the “low-voltage” signal is asserted. In response to assertion of the “low-voltage” signal, the controller completes a write cycle/program operation, if pending, and prevents any additional write cycles/program operation(s) during assertion of the “low-voltage” signal. | 02-12-2009 |
20090089481 | Leveraging Portable System Power to Enhance Memory Management and Enable Application Level Features - A memory device and techniques for its operation are presented. After operating on power received from a host, the memory device determines that it is no longer receiving host power and, in response, activates a power source on the memory device itself. Using this reserve power, the memory device can then perform data management operations. The techniques can also be applied to a digital appliance having a non-volatile memory. The memory device or digital appliance can prioritize its memory management operation during the host/user operating window based on the ability to perform these operations outside of the host/user operating window. Additionally, in a data write operations, where the memory device receives data from a host, stores the data in volatile memory, and then writes the data into the non-volatile memory, the memory device sends the host an acknowledgment of the data having been written into the non-volatile memory after it has been store in the volatile memory, but before the write into the non-volatile memory is complete. | 04-02-2009 |
20110154158 | SYSTEM AND METHOD OF ERROR CORRECTION OF CONTROL DATA AT A MEMORY DEVICE - A method includes initiating a compression operation to compress data to be stored in a group of storage elements at a memory device that includes an error correction coding (ECC) engine. The method includes selecting one of a first mode of the ECC engine to generate a first number of parity bits and a second mode of the ECC engine to generate a second number of parity bits based on an extent of compression of the data. The method also includes encoding the compressed data to generate parity bits corresponding to the compressed data and storing the compressed data and the parity bits to the group of storage elements according to a page format that includes a data portion and a parity portion. The compressed data is stored in the data portion and at least some of the parity bits are stored in the parity portion. | 06-23-2011 |
20110154160 | SYSTEM AND METHOD OF ERROR CORRECTION OF CONTROL DATA AT A MEMORY DEVICE - A controller coupled to a memory array includes an error correction coding (ECC) engine and an ECC enhancement compression module coupled to the ECC engine. The ECC enhancement compression module is configured to receive and compress control data to be provided to the ECC engine to be encoded. Compressed encoded control data generated at the ECC engine is stored as a codeword at the memory array. | 06-23-2011 |
20120023346 | METHODS AND SYSTEMS FOR DYNAMICALLY CONTROLLING OPERATIONS IN A NON-VOLATILE MEMORY TO LIMIT POWER CONSUMPTION - Systems and methods are disclosed for limiting power consumption of a non-volatile memory (NVM) using a power limiting scheme that distributes a number of concurrent NVM operations over time. This provides a “current consumption cap” that fixes an upper limit of current consumption for the NVM, thereby eliminating peak power events. In one embodiment, power consumption of a NVM can be limited by receiving data suitable for use as a factor in adjusting a current threshold from at least one of a plurality of system sources. The current threshold can be less than a peak current capable of being consumed by the NVM and can be adjusted based on the received data. A power limiting scheme can be used that limits the number of concurrent NVM operations performed so that a cumulative current consumption of the NVM does not exceed the adjusted current threshold. | 01-26-2012 |
20120023347 | METHODS AND SYSTEMS FOR DYNAMICALLY CONTROLLING OPERATIONS IN A NON-VOLATILE MEMORY TO LIMIT POWER CONSUMPTION - Systems and methods are disclosed for limiting power consumption of a non-volatile memory (NVM) using a power limiting scheme that distributes a number of concurrent NVM operations over time. This provides a “current consumption cap” that fixes an upper limit of current consumption for the NVM, thereby eliminating peak power events. In one embodiment, power consumption of a NVM can be limited by receiving data suitable for use as a factor in adjusting a current threshold from at least one of a plurality of system sources. The current threshold can be less than a peak current capable of being consumed by the NVM and can be adjusted based on the received data. A power limiting scheme can be used that limits the number of concurrent NVM operations performed so that a cumulative current consumption of the NVM does not exceed the adjusted current threshold. | 01-26-2012 |
20120023348 | METHODS AND SYSTEMS FOR DYNAMICALLY CONTROLLING OPERATIONS IN A NON-VOLATILE MEMORY TO LIMIT POWER CONSUMPTION - Systems and methods are disclosed for limiting power consumption of a non-volatile memory (NVM) using a power limiting scheme that distributes a number of concurrent NVM operations over time. This provides a “current consumption cap” that fixes an upper limit of current consumption for the NVM, thereby eliminating peak power events. In one embodiment, power consumption of a NVM can be limited by receiving data suitable for use as a factor in adjusting a current threshold from at least one of a plurality of system sources. The current threshold can be less than a peak current capable of being consumed by the NVM and can be adjusted based on the received data. A power limiting scheme can be used that limits the number of concurrent NVM operations performed so that a cumulative current consumption of the NVM does not exceed the adjusted current threshold. | 01-26-2012 |
20120023356 | PEAK POWER VALIDATION METHODS AND SYSTEMS FOR NON-VOLATILE MEMORY - Systems and methods are disclosed for validating a non-volatile memory (NVM) package for use in an electronic device before it is incorporated into the device. A NVM package may be validated by determining its power consumption profile, and if the profile meets predetermined criteria, that NVM package may be qualified for use in an electronic system. The power consumption profile may be obtained by issuing commands, such as read commands, to the NVM package to simultaneously access each die of the NVM package to invoke a maximum power consumption event. During this event, power consumption by the NVM package can be monitored and analyzed to determine whether the NVM package qualifies for use in an electronic device. | 01-26-2012 |
20130031009 | AD-HOC CASH DISPENSING NETWORK - An ad-hoc cash-dispensing network that allows users to efficiently exchange cash is provided. The ad-hoc cash-dispensing network includes a cash-dispensing server, a network, and a plurality of client terminals that connect to the cash-dispending server through the network. The user of a client terminal sends a request for cash to the cash-dispensing server. The request for cash includes the location of the client terminal. Based on this location, the cash-dispensing server locates one or more other users that are close/proximate to the requesting user and verifies that at least one of these proximate users is willing and able to provide the requested amount of cash. Following the transfer of cash between the parties, the requesting user's account is charged for the service while the providing user's account is credited for the service. | 01-31-2013 |
20130290606 | POWER MANAGEMENT FOR A SYSTEM HAVING NON-VOLATILE MEMORY - Systems and methods are disclosed for power management of a system having non-volatile memory (“NVM”). One or more controllers of the system can optimally turn modules on or off and/or intelligently adjust the operating speeds of modules and interfaces of the system based on the type of incoming commands and the current conditions of the system. This can result in optimal system performance and reduced system power consumption. | 10-31-2013 |
20140068296 | METHODS AND SYSTEMS FOR DYNAMICALLY CONTROLLING OPERATIONS IN A NON-VOLATILE MEMORY TO LIMIT POWER CONSUMPTION - Systems and methods are disclosed for limiting power consumption of a non-volatile memory (NVM) using a power limiting scheme that distributes a number of concurrent NVM operations over time. This provides a “current consumption cap” that fixes an upper limit of current consumption for the NVM, thereby eliminating peak power events. In one embodiment, power consumption of a NVM can be limited by receiving data suitable for use as a factor in adjusting a current threshold from at least one of a plurality of system sources. The current threshold can be less than a peak current capable of being consumed by the NVM and can be adjusted based on the received data. A power limiting scheme can be used that limits the number of concurrent NVM operations performed so that a cumulative current consumption of the NVM does not exceed the adjusted current threshold. | 03-06-2014 |