Abstract: An attenuating circuit for reducing the inductively induced voltage transients in an electrical signal. The attenuating circuit is formed by a primary circuit and a smoothing circuit both coupled to a voltage source through an inductive conductor. The primary circuit operates in two states having a first and second current draw, respectively. The smoothing circuit also has a first and second state and a first and second current draw, respectively. The current draws of the primary circuit and the smoothing circuit are such that the total current draw on the voltage source through the inductive conductor maintains relatively constant regardless of the state that the primary circuit is in, thus minimizing any induced voltage transients as a result of the conductor's inductance.

Abstract: An antifuse detection circuit is described which uses a latching circuit and two antifuses. The antifuses are coupled between the latch circuit and ground. The latching circuit described is a differential circuit which can detect which one of the two antifuses has been programmed. The circuit accurately detects an antifuse which has a relatively high resistance after being programmed.

Abstract: An attenuating circuit for reducing the inductively induced voltage transients in an electrical signal. The attenuating circuit is formed by a primary circuit and a smoothing circuit both coupled to a voltage source through an inductive conductor. The primary circuit operates in two states having a first and second current draw, respectively. The smoothing circuit also has a first and second state and a first and second current draw, respectively. The current draws of the primary circuit and the smoothing circuit are such that the total current draw on the voltage source through the inductive conductor maintains relatively constant regardless of the state that the primary circuit is in, thus minimizing any induced voltage transients as a result of the conductor's inductance.

Abstract: A test socket for testing a vertical surface mount packaged semiconductor device, the test socket including a test substrate, a support member, and clamps. The test substrate includes terminals which are electrically connectable to a testing device. The shape of the support member is complementary to the shape of the bottom surface of leads extending from the vertical surface mount packaged semiconductor device. The shape of the clamps is complementary to the top surface of the leads. The test substrate may also define lead alignment notches around one or more of the terminals. Upon placement of a vertical surface mount packaged semiconductor device on the test substrate, the leads are aligned with their corresponding terminals, then placed against the terminals and the support member. The clamps are then placed against the leads, biasing each of the leads against the support member and its corresponding terminal.

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: An antifuse detection circuit is described which uses a latching circuit and two antifuses. The antifuses are coupled between the latch circuit and ground. The latching circuit described is a differential circuit which can detect which one of the two antifuses has been programmed. The circuit accurately detects an antifuse which has a relatively high resistance after being programmed.

Abstract: A test circuit for a memory device having a pair of arrays each of which includes a plurality of memory cells arranged in rows and columns, and a pair of complimentary digit lines being provided for each column of each array. The digit lines are selectively coupled to a pair of I/O lines for each array which are, in turn, coupled to a pair of complimentary data lines. The data lines are coupled to respective inputs of a sense amplifier, one of which is provided for each array. A multiplexer connects the pair of I/O lines for either one of the arrays to the data lines in a normal operating mode. Thus, in the normal operating mode, data is selectively coupled to the inputs of the sense amplifier from the complimentary digit lines for an addressed column. In a test mode, the multiplexer connects an I/O line for one array to one of the data lines and an I/O line for the other array to the other data line.

Abstract: In a packetized memory device, pipelined 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 column path also includes a set of bank address latches so that bank addresses can be pipelined synchronously with column addresses. 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. The bank address latches also activate a selected bank responsive to the strobe.

Abstract: In a packetized memory device, pipelined 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 column path also includes a set of bank address latches so that bank addresses can be pipelined synchronously with column addresses. 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. The bank address latches also activate a selected bank responsive to the strobe.

Abstract: A sense amplifier that amplifies data signals in either a normal mode or an altered mode. In the normal mode, the data signals must be complementary of each other while in the altered mode, the data signals may, but need not be, complementary of each other. The sense amplifier includes two sense amplifier stages, the first of which drives the second, and each sense amplifier stage includes two identical sense amplifier circuits. A first input of each sense amplifier in the first stage receives a respective data signal, and a first input of each sense amplifier in the second stage receives an output signal from a respective sense amplifier in the first stage. In the normal mode, a mode control circuit couples each of the other data signals to a respective second input of each sense amplifier in the first stage so that the sense amplifiers receive both of the complimentary data signals at their differential inputs.

Abstract: A sense amplifier that amplifies data signals in either a normal mode or an altered mode. In the normal mode, the data signals must be complementary of each other while in the altered mode, the data signals may, but need not be, complementary of each other. The sense amplifier includes two sense amplifier stages, the first of which drives the second, and each sense amplifier stage includes two identical sense amplifier circuits. A first input of each sense amplifier in the first stage receives a respective data signal, and a first input of each sense amplifier in the second stage receives an output signal from a respective sense amplifier in the first stage. In the normal mode, a mode control circuit couples each of the other data signals to a respective second input of each sense amplifier in the first stage so that the sense amplifiers receive both of the complimentary data signals at their differential inputs.

Abstract: A memory device includes an output data path that transfers data from an I/O circuit coupled to a memory array to an output tri-state buffer. A comparing circuit compares data from the I/O circuit to a desired data pattern. If the data does not match the desired pattern, the comparing circuit outputs an error signal that is input to the output buffer. When the output buffer receives the error signal, the output buffer is disabled and outputs a tri-state condition on a data bus. Since the error signal corresponds to more than one data bit, the tri-state condition of the output buffer is held for more than one tick of the data clock, rather than only a single tick. Consequently, the tri-state condition remains on the bus for sufficiently long that a test system can detect the tri-state condition even at very high clock frequencies.

Abstract: A configurable integrated circuit has first and second externally accessible terminals. A configuration circuit has an input terminal coupled to the first externally accessible terminal and also has an output terminal. The configuration circuit receives a configuration input signal that represents a configuration and generates a configuration output signal that enables the represented configuration. A configuration indicator has an input terminal that is coupled to the output terminal of the configuration circuit and has an output terminal that is coupled to the second externally accessible terminal. The configuration indicator receives the configuration output signal from the configuration circuit and generates on the second externally accessible terminal an indicate signal that identifies the enabled configuration. The configuration circuit may include a plurality of output terminals and receive a configuration input signal that represents one or more configurations.

Abstract: An antifuse detection circuit is described which uses a latching circuit and two antifuses. The antifuses are coupled between the latch circuit and ground. The latching circuit described is a differential circuit which can detect which one of the two antifuses has been programmed. The circuit accurately detects an antifuse which has a relatively high resistance after being programmed.

Abstract: A test circuit for a memory device having a pair of arrays each of which includes a plurality of memory cells arranged in rows and columns, and a pair of complimentary digit lines being provided for each column of each array. The digit lines are selectively coupled to a pair of I/O lines for each array which are, in turn, coupled to a pair of complimentary data lines. The data lines are coupled to respective inputs of a sense amplifier, one of which is provided for each array. A multiplexer connects the pair of I/O lines for either one of the arrays to the data lines in a normal operating mode. Thus, in the normal operating mode, data is selectively coupled to the inputs of the sense amplifier from the complimentary digit lines for an addressed column. In a test mode, the multiplexer connects an I/O line for one array to one of the data lines and an I/O line for the other array to the other data line.

Abstract: A detection circuit for detecting unblown and blown conditions for an anti-fuse. The detection circuit includes a precharge circuit for applying a precharge to the anti-fuse during a precharge time interval, and a sampling circuit for coupling the anti-fuse to the detection node to provide a voltage at the detection node that is indicative of the ability of the anti-fuse to retain a charge during the discharge time interval. An output circuit that is coupled to the detection node is responsive to the voltage provided at the detection node to provide a first output for indicating an unblown condition for the anti-fuse and a second output for indicating a blown condition for the anti-fuse.

Abstract: An integrated circuit semiconductor device includes a charge pump to provide current at a potential which is greater than a supply potential. The charge pump utilizes an oscillator, which causes the charge pump to cycle, and thereby provide a continuous output at an elevated potential. In order to optimize efficiency of the charge pump, the oscillator is able to change its frequency in response to output potential. In the preferred embodiments, this is accomplished by selectively inserting a supplemental portion into a ring oscillator loop. When used with an integrated circuit device, such as a DRAM, the current from the charge pump may be supplied to nodes on isolation devices and nodes on word lines, thereby improving the performance of the DRAM without substantially changing the circuit configuration of the DRAM array.

Abstract: An integrated circuit semiconductor device includes a charge pump to provide current at a potential which is greater than a supply potential. The charge pump utilizes an oscillator, which causes the charge pump to cycle, and thereby provide a continuous output at an elevated potential. In order to optimize efficiency of the charge pump, the oscillator is able to change its frequency in response to output potential. In the preferred embodiments, this is accomplished by selectively inserting a supplemental portion into a ring oscillator loop. When used with an integrated circuit device, such as a DRAM, the current from the charge pump may be supplied to nodes on isolation devices and nodes on word lines, thereby improving the performance of the DRAM without substantially changing the circuit configuration of the DRAM array.