Abstract: A bidirectional repeater and data multiplexer for serial data has A-side 12C port devices A1-A4 coupled to comparators 302-308 and pull-downs to ground 316-322. Comparator outputs are coupled responsive to select lines S1-S4 of N:1 Select 310 to terminal A1 of bidirectional control 210 to control pull-down to non-zero low voltage Vp 206 at B-side device B. An inverting comparator 208 coupled to terminal B1 of bidirectional control 210 responds to input threshold voltage Vt less than low voltage Vp, to prevent data lockup due to data flowback to devices A1-A4. Output data from comparator 208 is coupled responsive to select lines S1-S4 of 1:N Select 312 to control pull-downs 316-322. This selectively repeats routing of device A1-A4 data to device B. Data from device B is selectively routed to pull-downs of devices A1-A4.

Abstract: A bidirectional repeater and data multiplexer for serial data has A-side 12C port devices A1-A4 coupled to comparators 302-308 and pull-downs to ground 316-322. Comparator outputs are coupled responsive to select lines S1-S4 of N:1 Select 310 to terminal A1 of bidirectional control 210 to control pull-down to non-zero low voltage Vp 206 at B-side device B. An inverting comparator 208 coupled to terminal B1 of bidirectional control 210 responds to input threshold voltage Vt less than low voltage Vp, to prevent data lockup due to data flowback to devices A1-A4. Output data from comparator 208 is coupled responsive to select lines S1-S4 of 1:N Select 312 to control pull-downs 316-322. This selectively repeats routing of device A1-A4 data to device B. Data from device B is selectively routed to pull-downs of devices A1-A4.

Abstract: A bidirectional repeater and data multiplexer for serial data has A-side I2C port devices A1-A4 coupled to comparators 302-308 and pulldowns to ground 316-322. Comparator outputs are coupled responsive to select lines S1-S4 of N:l Select 310 to terminal A1 of bidirectional control 210 to control pulldown to non-zero low voltage Vp 206 at B-side device B. An inverting comparator 208 coupled to terminal B1 of bidirectional control 210 responds to input threshold voltage Vt less than low voltage Vp, to prevent data lockup due to data flowback to devices A1-A4. Output data from comparator 208 is coupled responsive to select lines S1-S4 of 1:N Select 312 to control pulldowns 316-322. This selectively repeats routing of device A1-A4 data to device B. Data from device B is selectively routed to pulldowns of devices A1-A4.

Abstract: A bidirectional repeater and data multiplexer for serial data comprises a plurality of comparators 302, 304, 306, 308 coupled to the respective input/output (I/O) terminals of a plurality of serial data transceiver devices A1, A2, A3, A4 such as used in I2C communication. Also coupled to these I/O terminals is a plurality of active pulldowns 316, 318, 320, 322. The outputs of the comparators are coupled to N:1 Select 310 logic wherein the desired data input is selected responsive to select lines S1, S2, S3, S4. The output of the N:1 select logic is coupled to a bidirectional control circuit 210, which couples the selected data to the control terminal of an active pulldown 206 having its source coupled to a pulldown voltage Vp low enough to represent a logic “low” level but non-zero, and a drain connected to the I/O terminal of a device B.

Abstract: A high-speed front-multiplexed multi-channel LVDS-compatible repeater circuit that limits input leakage current levels in the event one or more input voltages of the circuit exceeds the supply voltage. The LVDS repeater includes a multiplexor having a plurality of differential inputs and at least one differential output. The multiplexor includes a plurality of transmission gates to allow any one of the differential inputs to be routed to any differential output. Each transmission gate includes a first PMOS transistor and an NMOS transistor. The multiplexor further includes first Schottky diodes coupled between Vcc and the back-gate nodes of the first PMOS transistors, and second PMOS transistors coupled as shunts between the gate nodes of the first PMOS transistors and the source nodes of the NMOS transistors.

Abstract: The present invention provides a method, system and apparatus for providing failsafe detection for a differential receiver. A bus activity signal (11) is activated when receiving a differential data signal of sufficient amplitude to transition through a predetermined threshold. A failsafe signal (620) indicates a low differential voltage condition. A countdown time period commences (85) upon activation of either signal, and a failsafe condition is determined (89) to exist if the failsafe signal is active (87) when the countdown time period expires (86).

Abstract: A high-speed front-multiplexed multi-channel LVDS-compatible repeater circuit that limits input leakage current levels in the event one or more input voltages of the circuit exceeds the supply voltage. The LVDS repeater includes a multiplexor having a plurality of differential inputs and at least one differential output. The multiplexor includes a plurality of transmission gates to allow any one of the differential inputs to be routed to any differential output. Each transmission gate includes a first PMOS transistor and an NMOS transistor. The multiplexor further includes first Schottky diodes coupled between Vcc and the back-gate nodes of the first PMOS transistors, and second PMOS transistors coupled as shunts between the gate nodes of the first PMOS transistors and the source nodes of the NMOS transistors.

Abstract: A driver (300) which meets wide common mode voltage requirements is provided. Output passgates (310) protect sensitive line driver circuitry (305) from extreme bus voltages; enabling/disabling circuits (315, 316) detect fault conditions to ensure the line driver is disabled when needed, and pull-ups (320) assist in line driver start up by preventing negative voltage conditions on the bus driven by the line driver.

Abstract: The present invention provides a method, system and apparatus for providing failsafe detection for a differential receiver. A bus activity signal (11) is activated when receiving a differential data signal of sufficient amplitude to transition through a predetermined threshold. A failsafe signal (620) indicates a low differential voltage condition. A countdown time period commences (85) upon activation of either signal, and a failsafe condition is determined (89) to exist if the failsafe signal is active (87) when the countdown time period expires (86).

Abstract: The present invention provides improved slew rate control over a varied operating temperature range. A switching device (P1, N1) receives from a predrive circuit (56) a control signal that limits a slew rate of the switching device's output and also varies proportionally to the operating temperature. In this manner, the effect of temperature on the slew rate can be reduced.

Abstract: The output slew rate of a differential transmission line driver (13) can be limited by suitably controlling signal slew rates (52) at the control inputs (neg, pos) of the drive switches (M1-M4) that control current flow through the load impedance (Rload) of the driver.

Abstract: The output slew rate of a differential transmission line driver (13) can be limited by suitably controlling signal slew rates (52) at the control inputs (neg, pos) of the drive switches (M1-M4) that control current flow through the load impedance (Rload) of the driver.