Abstract: The present invention is directed to a system, a module, and an apparatus and method for forming a microelectronic memory device. In one embodiment, a system includes a processor and a controller coupled to the processor with at least one memory module coupled to the controller, the module including a pair of memory devices oppositely positioned on respective surfaces of a substrate and interconnected by members extending through the substrate that couple terminals of the devices, the terminals being selected to include a group of terminals that are configured to communicate functionally compatible signals.

Abstract: An active termination circuit is used to set the input impedance of a plurality of input terminals. Each of the input terminals is coupled to a supply voltage through at least one PMOS transistor and to ground through at least one NMOS transistor. The impedances of the transistors are controlled by a control circuit that generates a first control signal to set the impedance of another PMOS transistor to be equal to a first predetermined resistance, and generates a second control signal to set the impedance of another NMOS transistor to be equal to a second predetermined resistance. The first control signal is used to control all of the PMOS transistors and the second control signal is used to control all of the NMOS transistors. As a result, the PMOS and NMOS transistors coupled to each input terminal have impedances corresponding to the first and second resistances, respectively.

Abstract: A lead frame includes at least two layers, each of which includes an electrically conductive bus and a group of leads that extend substantially unidirectionally from a single edge of the lead frame. The lead fingers of each layer may extend in substantially the same direction. The electrically conductive buses of the two or more lead frame layers are at least partially superimposed with respect to one another. An insulator element is disposed between at least portions of the superimposed regions of the buses. One of the buses is connectable to a power supply source (VCC), while the other is connectable to a power supply ground (VSS). Thus, the mutually superimposed regions of the buses form a decoupling capacitor. Lead fingers of one of the layers may be arranged in groups which flank the remainder of the lead fingers so that they are not interleaved therewith.

Abstract: A synchronous semiconductor memory device is operable in a normal mode and an alternative mode. The semiconductor device has a command bus for receiving a plurality of synchronously captured input signals, and a plurality of asynchronous input terminals for receiving a plurality of asynchronous input signals. The device further has a clock input for receiving an external clock signal thereon, with the device being specified by the manufacturer to be operated in the normal mode using an external clock signal having a frequency no less than a predetermined minimum frequency. An internal delay locked loop (DLL) clocking circuit is coupled to the clock input terminal and is responsive in normal operating mode to be responsive to the external clock signal to generate at least one internal clock signal.

Abstract: A system and method for selecting redundant rows and columns of memory devices includes a column select steering circuit to couple column select signals from a column address decoder to an array of memory cells. The system and method also includes a fuse banks for programming respective addresses of up to two defective columns that are to be repaired. The programmed addresses are applied to a defective column decoder that determines which column select signal(s) should be shifted downwardly and which column select signal(s) should be shifted upwardly. The column select steering circuit responds to signals from the defective column decoder to shift the column select signals downwardly or upwardly. The column select signal for the lowest column is shifted downwardly to a redundant column, and the column select signal for the highest column is shifted upwardly to a redundant column.

Abstract: An active termination circuit is used to set the input impedance of a plurality of input terminals. Each of the input terminals is coupled to a supply voltage through at least one PMOS transistor and to ground through at least one NMOS transistor. The impedances of the transistors are controlled by a control circuit that generates a first control signal to set the impedance of another PMOS transistor to be equal to a first predetermined resistance, and generates a second control signal to set the impedance of another NMOS transistor to be equal to a second predetermined resistance. The first control signal is used to control all of the PMOS transistors and the second control signal is used to control all of the NMOS transistors. As a result, the PMOS and NMOS transistors coupled to each input terminal have impedances corresponding to the first and second resistances, respectively.

Abstract: A method of reducing parasitic capacitance in an integrated circuit having three or more metal levels is described. The method comprises forming a bond pad at least partially exposed at the top surface of the integrated circuit, forming a metal pad on the metal level below the bond pad and forming an underlying metal pad on each of the one or more lower metal levels. In the illustrated embodiments, the ratio of an area of at least one of the underlying metal pads to the area of the bond pad is less than 30%. Parasitic capacitance is thus greatly reduced and signal propagation speeds improved.

Abstract: The present invention is directed to a system, a module, and an apparatus and method for forming a microelectronic memory device. In one embodiment, a system includes a processor and a controller coupled to the processor with at least one memory module coupled to the controller, the module including a pair of memory devices oppositely positioned on respective surfaces of a substrate and interconnected by members extending through the substrate that couple terminals of the devices, the terminals being selected to include a group of terminals that are configured to communicate functionally compatible signals.

Abstract: The read latency of a plurality of memory devices in a high speed synchronous memory subsystem is equalized through the use of at least one flag signal. The flag signal has equivalent signal propagation characteristics read clock signal, thereby automatically compensating for the effect of signal propagation. After detecting the flag signal, a memory device will begin outputting data associated with a previously received read command in a predetermined number of clock cycles. For each of the flag signal, the memory controller, at system initialization, determines the required delay between issuing a read command and issuing the flag signal to equalize the system read latencies. The delay(s) are then applied to read transactions during regular operation of the memory system.

Abstract: A synchronous semiconductor memory device is operable in a normal mode and an alternative mode. The semiconductor device has a command bus for receiving a plurality of synchronously captured input signals, and a plurality of asynchronous input terminals for receiving a plurality of asynchronous input signals. The device further has a clock input for receiving an external clock signal thereon, with the device being specified by the manufacturer to be operated in the normal mode using an external clock signal having a frequency no less than a predetermined minimum frequency. An internal delay locked loop (DLL) clocking circuit is coupled to the clock input terminal and is responsive in normal operating mode to be responsive to the external clock signal to generate at least one internal clock signal.

Abstract: A system and method for selecting redundant rows and columns of memory devices includes a column select steering circuit to couple column select signals from a column address decoder to an array of memory cells. The system and method also includes a fuse banks for programming respective addresses of up to two defective columns that are to be repaired. The programmed addresses are applied to a defective column decoder that determines which column select signal(s) should be shifted downwardly and which column select signal(s) should be shifted upwardly. The column select steering circuit responds to signals from the defective column decoder to shift the column select signals downwardly or upwardly. The column select signal for the lowest column is shifted downwardly to a redundant column, and the column select signal for the highest column is shifted upwardly to a redundant column.

Abstract: An active termination circuit is used to set the input impedance of a plurality of input terminals. Each of the input terminals is coupled to a supply voltage through at least one PMOS transistor and to ground through at least one NMOS transistor. The impedances of the transistors are controlled by a control circuit that generates a first control signal to set the impedance of another PMOS transistor to be equal to a first predetermined resistance, and generates a second control signal to set the impedance of another NMOS transistor to be equal to a second predetermined resistance. The first control signal is used to control all of the PMOS transistors and the second control signal is used to control all of the NMOS transistors. As a result, the PMOS and NMOS transistors coupled to each input terminal have impedances corresponding to the first and second resistances, respectively.

Abstract: The read latency of a plurality of memory devices in a high speed synchronous memory subsystem is equalized through the use of at least one flag signal. The flag signal has equivalent signal propagation characteristics read clock signal, thereby automatically compensating for the effect of signal propagation. After detecting the flag signal, a memory device will begin outputting data associated with a previously received read command in a predetermined number of clock cycles. For each of the flag signal, the memory controller, at system initialization, determines the required delay between issuing a read command and issuing the flag signal to equalize the system read latencies. The delay(s) are then applied to read transactions during regular operation of the memory system.

Abstract: A method for storing a temperature threshold in an integrated circuit includes measuring operating parameters of the integrated circuit versus temperature, calculating a maximum temperature at which the integrated circuit performance exceeds predetermined specifications and storing parameters corresponding to the maximum temperature in a comparison circuit in the integrated circuit by selectively blowing fusable devices in the comparison circuit. The fusable devices may be antifuses.

Abstract: A system and method for selecting redundant rows and columns of memory devices includes a column select steering circuit to couple column select signals from a column address decoder to an array of memory cells. The system and method also includes a fuse banks for programming respective addresses of up to two defective columns that are to be repaired. The programmed addresses are applied to a defective column decoder that determines which column select signal(s) should be shifted downwardly and which column select signal(s) should be shifted upwardly. The column select steering circuit responds to signals from the defective column decoder to shift the column select signals downwardly or upwardly. The column select signal for the lowest column is shifted downwardly to a redundant column, and the column select signal for the highest column is shifted upwardly to a redundant column.

Abstract: In a packetized memory device, row and column address paths receive row and column addresses from an address capture circuit. Each of the row and column address paths includes a respective address latch that latches the row or column address from the address capture circuitry, thereby freeing the address capture circuitry to capture a subsequent address. The latched row and column addresses are then provided to a combining circuit. Additionally, redundant row and column circuits receive these latched addresses and indicate to the combining circuit whether or not to substitute a redundant row. The combining circuit, responsive to a strobe then transfers the redundant row address or latched row address to a decoder to activate the array.

Abstract: A synchronous semiconductor memory device is operable in a normal mode and an alternative mode. The semiconductor device has a command bus for receiving a plurality of synchronously captured input signals, and a plurality of asynchronous input terminals for receiving a plurality of asynchronous input signals. The device further has a clock input for receiving an external clock signal thereon, with the device being specified by the manufacturer to be operated in the normal mode using an external clock signal having a frequency no less than a predetermined minimum frequency. An internal delay locked loop (DLL) clocking circuit is coupled to the clock input terminal and is responsive in normal operating mode to be responsive to the external clock signal to generate at least one internal clock signal.

Abstract: The present invention is directed to a system, a module, and an apparatus and method for forming a microelectronic memory device. In one embodiment, a system includes a processor and a controller coupled to the processor with at least one memory module coupled to the controller, the module including a pair of memory devices oppositely positioned on respective surfaces of a substrate and interconnected by members extending through the substrate that couple terminals of the devices, the terminals being selected to include a group of terminals that are configured to communicate functionally compatible signals.

Abstract: The read latency of a plurality of memory devices in a high speed synchronous memory subsystem is equalized through the use of at least one flag signal. The flag signal has equivalent signal propagation characteristics read clock signal, thereby automatically compensating for the effect of signal propagation. After detecting the flag signal, a memory device will begin outputting data associated with a previously received read command in a predetermined number of clock cycles. For each of the flag signal, the memory controller, at system initialization, determines the required delay between issuing a read command and issuing the flag signal to equalize the system read latencies. The delay(s) are then applied to read transactions during regular operation of the memory system.

Abstract: A lead frame assembly including at least two layers. A first of the lead frame layers includes a first wide, electrically conductive bus and a plurality of leads that extend substantially unidirectionally from a single edge of the lead frame assembly. The second lead frame layer includes a second wide, electrically conductive bus that is superimposed over the first bus and a plurality of lead fingers extending substantially unidirectionally from a single edge of the lead frame assembly. Preferably, the lead fingers of both the first and second layers extend in substantially the same direction. An insulator element is disposed between the first and second buses. One of the buses is connectable to a power supply source (Vcc), while the other is connectable to a power supply ground (Vss). Thus, the co-extensive portions of the first and second buses form a decoupling capacitor.