Abstract: An integrated circuit with a flexible data strobe signal (DQS) bus structure is presented. The integrated circuit has a number of input/output (I/O) modules with a number of data pins to receive and transmit data. In addition, a subset of the I/O modules also have a data strobe pin. The input/output modules are connected to data strobe signal buses having a fixed configuration. The configuration of the fixed DQS bus groups a number of data pins with a corresponding data strobe pin and the grouping of data pin spans multiple I/O modules. The integrated circuit also has a flexible data bus connected to the I/O modules. Data pins of I/O modules of a second integrated circuit are mapped a subset of the data pins of corresponding I/O modules of the integrated circuit. The flexible data strobe signal bus enables selection of the subset of data pins in the integrated circuit.

Abstract: A circuit can include a module having signal pads that are configurable to route signals between the circuit and at least one external device. The module can also have unused pads that are interleaved between the signal pads. A circuit can include a module having signal pads that are configurable to route varying signals between the circuit and at least one external device. The module can also have voltage pads that are configurable to route substantially constant voltages between at least one external device and the circuit. The signal pads can be interleaved between the voltage pads. A module with one or more of these features can achieve ideal performance in both wire bond and flip chip packages with the flexibility of setting a different input/output utilization percentage within the module.

Abstract: A circuit can include a module having signal pads that are configurable to route signals between the circuit and at least one external device. The module can also have unused pads that are interleaved between the signal pads. A circuit can include a module having signal pads that are configurable to route varying signals between the circuit and at least one external device. The module can also have voltage pads that are configurable to route substantially constant voltages between at least one external device and the circuit. The signal pads can be interleaved between the voltage pads. A module with one or more of these features can achieve ideal performance in both wire bond and flip chip packages with the flexibility of setting a different input/output utilization percentage within the module.

Abstract: Integrated circuits are provided that have sensitive circuitry such as programmable polysilicon fuses. Electrostatic discharge (ESD) protection circuitry is provided that prevents damage or undesired programming of the sensitive circuitry in the presence of an electrostatic discharge event. The electrostatic discharge protection circuitry may have a power ESD device that limits the voltage level across the sensitive circuitry to a maximum voltage and that draws current away from the sensitive circuitry when exposed to ESD signals. The electrostatic discharge protection circuitry may also have an ESD margin circuit that helps to prevent current flow through the sensitive circuitry when the maximum voltage is applied across the sensitive circuitry.

Abstract: Circuits, methods, and apparatus for ordering the timing of clock and data signals. Programmable delay cells are utilized in a data output cell to control a critical multiple data rate input/output write timing so the output can achieve better performance, such as higher maximum frequency of output (Fmax) performance. The delay cells ensure that critical timing criteria between clock signals and data high and low signals are satisfied so that there is a reduced chance of output glitching.

Abstract: Integrated circuits are provided that have sensitive circuitry such as programmable polysilicon fuses. Electrostatic discharge (ESD) protection circuitry is provided that prevents damage or undesired programming of the sensitive circuitry in the presence of an electrostatic discharge event. The electrostatic discharge protection circuitry may have a power ESD device that limits the voltage level across the sensitive circuitry to a maximum voltage and that draws current away from the sensitive circuitry when exposed to ESD signals. The electrostatic discharge protection circuitry may also have an ESD margin circuit that helps to prevent current flow through the sensitive circuitry when the maximum voltage is applied across the sensitive circuitry.

Abstract: Circuits are described that provide electrostatic discharge protection for I/O circuits that support the low voltage differential signaling (LVDS) and on-chip termination (OCT) standards. At least one additional transistor is connected across an I/O transistor. In the case of LVDS, a pair of stacked transistors is used in which the distance between the source/drain region and a well tap is considerably greater for the transistor connected to the I/O pad. A PMOS transistor and an NMOS transistor may also be connected in series between a first node such as a power supply node and the I/O pad. An OCT circuit is also disclosed in which the spacing between the source/drain region and a well tap in the OCT transistor is smaller than that in the I/O transistor.