Abstract: An integrated circuit memory device is designed for high speed data access and for compatibility with existing memory systems. An address strobe signal is used to latch a first address. During a burst access cycle the address is incremented internal to the device with additional address strobe transitions. A new memory address is only required at the beginning of each burst access. Read/Write commands are issued once per burst access eliminating the need to toggle the Read/Write control line at the device cycle frequency. Transitions of the Read/Write control line during a burst access will terminate the burst access, reset the burst length counter and initialize the device for another burst access. The device is compatible with existing Extended Data Out DRAM device pinouts, Fast Page Mode and Extended Data Out Single In-Line Memory Module pinouts, and other memory circuit designs.

Abstract: An address strobe latches a first address. A burst cycle increments the address internally with additional address strobes. A new memory address is only required at the beginning of each burst access. Read/Write commands are issued once per burst access eliminating toggling Read/Write control line at cycle frequency. Control line transition terminates access and initializes another burst access. Write cycle times are maximized thereby allowing increases in burst mode operating frequencies. Logic near sense amplifiers control write-data drivers thereby providing maximum write times without crossing current during I/O line equilibration. By gating global write-enable signals with global equilibrate signals locally at sense amps, local write-cycle control signals are provided and valid for essentially the entire cycle time minus an I/O line equilibration period in burst access memory.

Abstract: An integrated circuit memory device is designed for high speed data access and for compatibility with existing memory systems. An address strobe signal is used to latch a first address. During a burst access cycle the address is incremented internal to the device with additional address strobe transitions. A new memory address is only required at the beginning of each burst access. Read/Write commands are issued once per burst access eliminating the need to toggle the Read/Write control line at the device cycle frequency. Transitions of the Read/Write control line during a burst access will terminate the burst access, reset the burst length counter and initialize the device for another burst access. The device is compatible with existing Extended Data Out DRAM device pinouts, Fast Page Mode and Extended Data Out Single In-Line Memory Module pinouts, and other memory circuit designs.

Abstract: A memory integrated circuit having three layers of metallic traces disposed over a substrate assembly including various active devices. The traces are arranged to include I/O traces that are continuous in the third layer across spans of 4 or 8 memory blocks of an array, and that are interspersed on the third layer with non-I/O lines adapted to reduce interference between I/O lines. Column select lines, orthogonal to I/O lines and disposed in the third layer of metallic traces, except in the vicinity of I/O lines, are provided in a linear configuration and shielded from parallel digit lines in the first layer of traces by traces of the intervening second layer of traces. Global bleeder lines disposed in the third layer of traces are adapted to apply a standby voltage to a plurality of sense amplifiers. Other features of the invention include two layer power and ground bus traces, and row decoder and phase driver circuits disposed in throat and gap cell regions respectively.

Abstract: A memory device includes a control circuit for initiating a read operation and a write operation in response to a combination of input signals during a setup time. The setup time is a time interval during which all input signals must remain valid before a next appearance of a rising edge of a clock signal. The control circuit uses the setup time to send a signal from one part of the memory to another part of the memory to avoid a signal propagation delay time. The memory device also includes a circuit for preparing the memory device for the write operation before the setup time.

Abstract: An address strobe latches a first address. A burst cycle increments the address internally with additional address strobes. A new memory address is only required at the beginning of each burst access. Read/Write commands are issued once per burst access eliminating toggling Read/Write control line at cycle frequency. Control line transition terminates access and initializes another burst access. Write cycle times are maximized thereby allowing increases in burst mode operating frequencies. Logic near sense amplifiers control write-data drivers thereby providing maximum write times without crossing current during I/O line equilibration. By gating global write-enable signals with global equilibrate signals locally at sense amps, local write-cycle control signals are provided and valid for essentially the entire cycle time minus an I/O line equilibration period in burst access memory.

Abstract: An integrated circuit memory device is designed to perform high speed data write cycles. An address strobe signal is used to latch a first address. During a burst access cycle the address is incremented internal to the device with additional address strobe transitions. A new memory address is only required at the beginning of each burst access. Read/Write commands are issued once per burst access eliminating the need to toggle the Read/Write control line at the device cycle frequency. A transition of the Read/Write control line during a burst access is used to terminate the burst access and initialize the device for another burst access. Write cycle times are maximized to allow for increases in burst mode operating frequencies. Local logic gates near array sense amplifiers are used to control write data drivers to provide for maximum write times without crossing current during input/output line equilibration periods.

Abstract: A memory integrated circuit having three layers of metallic traces disposed over a substrate assembly including various active devices. The traces are arranged to include I/O traces that are continuous in the third layer across spans of 4 or 8 memory blocks of an array, and that are interspersed on the third layer with non-I/O lines adapted to reduce interference between I/O lines. Column select lines, orthogonal to I/O lines and disposed in the third layer of metallic traces, except in the vicinity of I/O lines, are provided in a linear configuration and shielded from parallel digit lines in the first layer of traces by traces of the intervening second layer of traces. Global bleeder lines disposed in the third layer of traces are adapted to apply a standby voltage to a plurality of sense amplifiers. Other features of the invention include two layer power and ground bus traces, and row decoder and phase driver circuits disposed in throat and gap cell regions respectively.

Abstract: An apparatus and method using a reduced number of fuses for enabling redundant memory blocks in a semiconductor memory is disclosed. In one embodiment, a redundancy selection module may be configured using selection fuses, wherein each selection fuse selects a pair of repair modules. In another embodiment, a redundancy selection module may be configured using selection fuses, wherein each selection fuse may select a power of two (i.e., 1, 2, 4, 8, etc.) number of repair modules. Each repair module includes fuses programmed with a selected address, such that the repair module may respond when an address input matches the selected address. However, the Least Significant Bit (LSB) is uninvolved in the address programming. Instead, the LSB is compared to the values of the selection fuses. As a result, repair modules select a redundant memory block based on a combination of the selected address comparison and the separate LSB comparison.

Abstract: The present invention reduces the area on a die required for rows and columns of redundant memory cells by sharing compare circuitry with banks of redundant memory cells based on division of the primary memory array into two or more “planes.” Pass gates or multiplexers coupled between at least two banks of fuses and one compare circuit selectively couple the appropriate fuse bank to the compare circuit. Preferably, a bit in the address (e.g., address bit RA9 in a row address word having address bits A0-RA9) is received by and controls the multiplexer to select between the two banks of fuses. Additionally, the planes span blocks of memory in the memory array, where each block is divided by shared sense amplifiers. As a result, while eight lines are coupled to 16 rows or columns, only eight rows or columns will be active at any one time because isolation gates will enable only eight of the 16 rows or columns within two planes of memory.

Abstract: An apparatus and method using a reduced number of nonvolatile programming elements for enabling redundant memory blocks in a semiconductor memory is disclosed. A redundancy selection module may be configured using N fuses to configure and select 2N-1 repair modules. Programming fuses effectively separates the repair modules into two sets, those with an even address and those with an odd address. Each repair module contains fuses programmed with a selected address, such that the repair module may respond when an address input matches the selected address. However, the least significant bit is left out of the programming. As a result, repair modules in the even set respond to even addresses matching the selected address and repair modules in the odd set respond to odd addresses matching the selected address. Similar arrangements may be used to reduce the number of enable fuses and disable fuses required for each repair module.

Abstract: An apparatus and method using a reduced number of nonvolatile programming elements for enabling redundant memory blocks in a semiconductor memory is disclosed. A redundancy selection module may be configured using N fuses to configure and select 2N?1 repair modules. Programming fuses effectively separates the repair modules into two sets, those with an even address and those with an odd address. Each repair module contains fuses programmed with a selected address, such that the repair module may respond when an address input matches the selected address. However, the least significant bit is left out of the programming. As a result, repair modules in the even set respond to even addresses matching the selected address and repair modules in the odd set respond to odd addresses matching the selected address. Similar arrangements may be used to reduce the number of enable fuses and disable fuses required for each repair module.

Abstract: An apparatus and method using a reduced number of fuses for enabling redundant memory blocks in a semiconductor memory is disclosed. In one embodiment, a redundancy selection module may be configured using selection fuses, wherein each selection fuse selects a pair of repair modules. In another embodiment, a redundancy selection module may be configured using selection fuses, wherein each selection fuse may select a power of two (i.e., 1, 2, 4, 8, etc.) number of repair modules. Each repair module includes fuses programmed with a selected address, such that the repair module may respond when an address input matches the selected address. However, the Least Significant Bit (LSB) is uninvolved in the address programming. Instead, the LSB is compared to the values of the selection fuses. As a result, repair modules select a redundant memory block based on a combination of the selected address comparison and the separate LSB comparison.

Abstract: A memory integrated circuit can be used either alone or as a pair to provide a memory device having twice the capacity of the single integrated circuit. The larger capacity memory device is addressed using an extra row address bit. The extra row address bit is used either to alternately enable each of the memory integrated circuits in one configuration or is remapped to become an extra column address bit in another configuration.

Abstract: A method, apparatus, and system are provided for implementing a zero-enabled fuse system. An apparatus includes a first set of fuses for activating a first memory portion, and a second set of fuses for activating a second memory portion. The apparatus also includes a controller to control an operation of the first and second set of fuses. The controller is adapted to determine whether a zero address memory location relating to the first memory portion is to be activated based upon an enable fuse. The controller is adapted to also perform a check to determine whether the second set of fuses has been previously activated.

Abstract: A memory device for reducing the number of data read lines needed in a memory device. Specifically, multiple helper flip-flops are used to prefetch data in a memory device. The helper flip-flops are configured to latch one or two of the data bits from a 4-bit prefetch in an alternating periodic fashion, thereby necessitating fewer data lines.

Abstract: An apparatus and method using a reduced number of nonvolatile programming elements for enabling redundant memory blocks in a semiconductor memory is disclosed. A redundancy selection module may be configured using N fuses to configure and select 2N?1 repair modules. Programming fuses effectively separates the repair modules into two sets, those with an even address and those with an odd address. Each repair module contains fuses programmed with a selected address, such that the repair module may respond when an address input matches the selected address. However, the least significant bit is left out of the programming. As a result, repair modules in the even set respond to even addresses matching the selected address and repair modules in the odd set respond to odd addresses matching the selected address. Similar arrangements may be used to reduce the number of enable fuses and disable fuses required for each repair module.

Abstract: An apparatus and method using a reduced number of fuses for enabling redundant memory blocks in a semiconductor memory is disclosed. In one embodiment, a redundancy selection module may be configured using selection fuses, wherein each selection fuse selects a pair of repair modules. In another embodiment, a redundancy selection module may be configured using selection fuses, wherein each selection fuse may select a power of two (i.e., 1, 2, 4, 8, etc.) number of repair modules. Each repair module includes fuses programmed with a selected address, such that the repair module may respond when an address input matches the selected address. However, the Least Significant Bit (LSB) is uninvolved in the address programming. Instead, the LSB is compared to the values of the selection fuses. As a result, repair modules select a redundant memory block based on a combination of the selected address comparison and the separate LSB comparison.

Abstract: A memory integrated circuit having three layers of metallic traces disposed over a substrate assembly including various active devices. The traces are arranged to include I/O traces that are continuous in the third layer across spans of 4 or 8 memory blocks of an array, and that are interspersed on the third layer with non-I/O lines adapted to reduce interference between I/O lines. Column select lines, orthogonal to I/O lines and disposed in the third layer of metallic traces, except in the vicinity of I/O lines, are provided in a linear configuration and shielded from parallel digit lines in the first layer of traces by traces of the intervening second layer of traces. Global bleeder lines disposed in the third layer of traces are adapted to apply a standby voltage to a plurality of sense amplifiers. Other features of the invention include two layer power and ground bus traces, and row decoder and phase driver circuits disposed in throat and gap cell regions respectively.

Abstract: A data amplifier configured to allow for fewer data lines and/or increased processing speeds. Specifically, multiple helper flip-flops are used to prefetch data in a data amplifier. The helper flip-flops are configured to latch one or two of the data bits from a 4-bit prefetch in an alternating periodic fashion, thereby necessitating fewer data lines. Alternatively, the number of data lines can be maintained and faster bus processing speeds may be realized.