Abstract: A micro-relay replaces electromechanical and solid-state opto-isolated relays in a computer network. The micro relay is an integrated circuit containing several bus switches in parallel. Each bus switch can make or break a connection. The bus switch is an n-channel MOS transistor with the source and drain connected to different network busses. A bus enable input causes the connection to be made or broken. The bus enable input is separately buffered for each gate of each MOS transistor to prevent crosstalk between bus switches. Since the MOS transistor stops conducting when the source is at a voltage level of the power-supply voltage minus the threshold voltage, a boosted voltage is applied to the gate of the MOS transistor to allow conduction even when the source is at the power-supply voltage level. The boosted voltage is generated by a charge pump. A substrate bias is applied to the transistors to prevent crosstalk from undershoots.

Abstract: A synchronizer that has reduced latency is used for synchronizing and conditioning a clock-enable signal to a free-running clock. Once the clock-enable signal is synchronized it is used to enable and disable gating of the free-running clock to a gated clock that suspends pulsing in response to the clock-enable signal. A first-stage flip-flop is `meta-stable hardened` to reduce the probability of it becoming meta-stable. Gating on the clock and the clear inputs reduces the chance that simultaneous inputs will violate the timing of the flip-flop and thus cause metastability. A clear pulse is generated to clear the flip-flop. The clear pulse skews the flip-flop to be more likely to become metastable for one edge of the asynchronous input than for the other edge. The settling time to the second stage flip-flop is then adjusted to account for this skew in metastability. Settling time in the second stage is increased for the edge that is more likely to become metastable.

Abstract: A non-volatile memory cell uses a p+ diffusion region spaced a lateral distance from the n+ drain of the n-channel programmable transistor. A diode between this p+ diffusion and the n+ drain has a low breakdown voltage because of the close spacing of the high-doping n+ and p+ diffusions. This diode generates electrons when avalanche breakdown occurs. The avalanche electrons are swept up into the programmable gate during programming. Since the avalanche electrons are generated by the diode rather than by the programmable transistor itself, programming efficiency no longer depends on the channel length and other parameters of the programmable transistor. The breakdown voltage of the diode is adjusted by varying the lateral spacing between the n+ drain and the p+ diffusion. Smaller lateral spacing enter avalanche breakdown at lower voltages and thus program the programmable transistor at a lower drain voltage.

Abstract: A network switch uses a simple switch core of analog MOS transistor switches. The switch core is surrounded by many media-access controllers (MAC's) which buffer the data through the switch core. Multiple connections through the switch core may be made between different pairs of MAC's. Just one signal path through the switch core is needed per connection as a second path through the switch core for the clock is not needed. The clock is not encoded with the data, so PLL's are not needed for clock recovery. Data skew is instead measured for each packet transmitted through the switch core. A start flag is added to the packet by a source MAC as a packet header before being transmitted through the switch core. The start flag is a unique sequence which is detected by the destination MAC and triggers measurement of the data skew of the received start flag to the local clock. The measured data skew is then used to compensate for the rest of the packet.

Abstract: A CMOS output buffer has a first stage with smaller driver transistors and a second stage having larger driver transistors. Both stages drive the output in parallel during the first half of a voltage transition, but the larger, second stage is disabled during the second half of the output voltage swing. The output voltage is fed back to an isolation circuit by a pulse generator which is triggered by the output reaching the switching threshold. The pulse generated disables the larger driver for a short period of time but later re-enables the driver. Thus the large driver remains on after the switching is complete, providing large IOH and IOL static currents. The pulse is long enough to keep the large driver disabled while reflections are received and ringing occurs after the voltage transition. Resistors in the smaller first stage absorb these reflections.

Abstract: A substrate bias generator for an integrated circuit has a charge pump driven by an oscillator. The oscillator is enabled and disabled to save power and control the voltage-level itself for the substrate bias. An enabling circuit senses the substrate voltage and enables the oscillator when the substrate voltage rises above a bias set by a programmable reference voltage. The enabling circuit which senses the voltage on the substrate draws no active current from the substrate. The sensing circuit includes a transistor with only its bulk terminal connected to the substrate; the source, gate, and drain of this sensing transistor are not connected to the substrate. A differential comparator compares the output of the sensing transistor to the programmable reference voltage and enables the oscillator when the sensing transistor output is lower than the reference voltage.

Abstract: A method for a frequency synthesizer with adaptive loop bandwidth is disclosed, which is adjusted by the improved frequency synthesizer includes a phase-locked loop and a phase-locked loop adjustment circuit. The phase-locked loop has loop characteristics including a loop bandwidth, a natural frequency, a damping factor, and the like. The phase-locked loop adjustment circuit is adjusted in response to a change in output frequency.

Abstract: A jitter attenuator receives data and a receive clock extracted from an input data stream. A transmit clock is generated for retransmitting the data. The transmit clock has less jitter than the receive clock but has the same average frequency. An elastic buffer or FIFO is necessary to buffer the data. The receive clock is divided into a series of write clocks for writing data into the elastic buffer, and the transmit clock is also divided into a series of read clocks for reading data from the elastic buffer. A series of multi-phase clocks is used to generate the transmit clock. The multi-phase clocks all have the same frequency but are offset in phase from one another. A phase selector, under control of a counter, selects one of the multi-phase clocks to be the transmit clock. The counter is incremented or decremented by a phase comparator. The phase comparator compares the phase of one of the write clocks to the phase of one of the read clocks.

Abstract: A jitter attenuator receives data and a receive clock extracted from an input data stream. A transmit clock is generated for retransmitting the data. The transmit clock has less jitter than the receive clock but has the same average frequency. An elastic buffer or FIFO is necessary to buffer the data. The receive clock is divided into a series of write clocks for writing data into the elastic buffer, and the transmit clock is also divided into a series of read clocks for reading data from the elastic buffer. A series of multi-phase clocks is used to generate the transmit clock. The multi-phase clocks all have the same frequency but are offset in phase from one another. A phase selector, under control of a counter, selects one of the multi-phase clocks to be the transmit clock. The counter is incremented or decremented by a phase comparator. The phase comparator compares the phase of one of the write clocks to the phase of one of the read clocks.

Abstract: An all-CMOS output buffer drives a bus that can operate at 3 volts and 5 volts. When in a high-impedance state, the output buffer draws little or no current. If the bus is driven to 5 volts by an external device, the high impedance output buffer is in danger of latch-up and distortion of the bus logic level since it only has a 3-volt power supply and does not use a charge pump or an extra 5-volt supply. A biasing circuit couples an N-well that contains p-channel transistors and a driver transistor to the bus driven to 5 volts. Thus the N-well is also driven to 5 volts, the voltage on the bus. The gate of the p-channel driver transistor in the high-impedance output buffer is also coupled to the N-well by another p-channel transistor, raising the gate potential to 5 volts. Thus the gate and body of the p-channel driver transistor is at 5 volts, eliminating reversing current and latch-up problems. A transmission gate isolates the gate of the p-channel driver transistor from the rest of the device's circuitry.