Abstract: An electro-static-discharge (ESD) protection circuit is coupled between power and ground. It protects core circuits in a semiconductor chip. The ESD protection circuit is an active circuit that drives the gate of an n-channel clamp transistor. The clamp transistor shunts current from power to ground when its gate is driven high during an ESD event. A voltage divider generates a sense voltage that drives a first inverter. The sense voltage is normally much lower than the switch threshold of the first inverter. When an ESD voltage spike occurs, the sense voltage rises above the switch threshold, switching the output of the first inverter. A string of inverters is driven by the first inverter, with a final inverter driving the gate of the clamp transistor. An extending n-channel transistor drives the input of the final inverter low when the clamping transistor is on, extending the discharge time.

Abstract: A differential buffer/driver has a switch network that connects an IOH current source to a differential output to be drive high, and connects an IOL current source to the other differential output to be driven low. Each output can be connected to a pull-down boost current sink. A boost pulse momentarily connects a boost current sink to the differential output being driven low. The differential buffer generates a pair of boost pulses to activate the boost current for either differential output. One boost pulse is activated when one differential output is driven low, while the other boost pulse is activated when the other differential output is driven low.

Abstract: A voltage-variable capacitor is constructed from a metal-oxide-semiconductor transistor. The transistor source has at least two contacts that are biased to different voltages. The source acts as a resistor with current flowing from an upper source contact to a lower source contact. The gate-to-source voltage varies as a function of the position along the source-gate edge. A critical voltage is where the gate-to-source voltage is equal to the transistor threshold. A portion of the source has source voltages above the critical voltage and no conducting channel forms under the gate. Another portion of the source has source voltages below the critical voltage, and thus a conducting channel forms under the gate for this portion of the capacitor. By varying either the gate voltage or the source voltages, the area of the gate that has a channel under it is varied, varying the capacitance. Separate source islands eliminate source current.

Abstract: A fail-safe circuit for a pair of differential input lines detects when one or both lines are open. Each line has a pull-up of a switched p-channel transistor in series with a resistor or another p-channel transistor that has its effective resistance controlled by a gate bias. The gate of the switched p-channel transistor is driven to ground when power is applied to the gate of a grounding n-channel transistor. When power is off, a p-channel connecting transistor charges the gate node from the differential input line when a positive voltage is applied to the input line, such as during a leakage test. Charging the gate node prevents the switched p-channel transistor from turning on, blocking a leakage current path through the pull-up. An N-well bias circuit can be added, which connects the N-well under p-channel transistors to power or the gate node or the input line.

Abstract: A clock modulator spreads the frequency spectrum of an input clock to generate an output clock. A capacitor is connected to an intermediate clock node by a load-switching transistor. When the transistor is turned on, the capacitor increases the loading on the intermediate clock node, increasing delay. When the transistor is turned off, the delay is reduced. Output clock cycle periods are extended when delay is added, and reduced when the transistor turns off. A counter or sequencer is clocked by the input clock and drives the load-switching transistor. The transistor is turned on and off for alternate cycles when the counter is a toggle flip-flop, spreading the frequency over two frequencies every two clock cycles. Two capacitors of different sizes, connected to the intermediate clock node by two transistors, can be switched by a 2-bit sequencer, spreading the output clock over 7 frequencies every 7 clock cycles.

Abstract: A substrate bias generator has a ring oscillator disabled when a supply over-voltage condition is detected by a supply comparator, or when a target substrate voltage is reached. A substrate comparator compares the substrate voltage to a reference generated by a p-channel sense transistor that is independent of the substrate voltage. The substrate is sensed by an n-channel sense transistor with only its bulk connected to the substrate voltage. Current sources for the sense transistors and comparator are controlled by bias voltages generated by a voltage divider that switches from a high-power state to a low-power state once the substrate target is reached. Feedback turns off a high-current resistor, limiting current to that passing through a low-current resistor. The bias voltages are adjusted to reduce current to the sense transistors and comparator, reducing power. High current and power are used for fast sensing before the substrate target is reached.

Abstract: An active terminating circuit has buffers to produce wider voltage drives on clamping transistors. A transmission line drives coupling capacitors. One capacitor drives an upper node that drives the gate of an upper buffer transistor. The upper buffer transistor drives a p-gate node coupled to a gate of a p-channel clamping transistor. The other capacitor drives a lower node that drives the gate of a lower buffer transistor, which drives an n-gate node of an n-channel clamping transistor. The drains of the clamping transistors are connected to the transmission line. Resistors pull the lower node to the power-supply voltage and pull the upper node to ground when no transitions occur on the transmission line, achieving zero standby power. When a transition is detected, it is coupled through the capacitors and buffered to the p-gate and n-gate nodes. Limiting transistors limit upper and lower node swings.

Abstract: A phase-locked loop (PLL) or a delay-locked loop (DLL) has differential delay stages with differential outputs driving differential clock inputs to a pair of differential toggle flip-flops. One flip-flop changes state on the rising edge and the other on the falling edge of the true output from the delay stage. Differential-to-single-ended buffers convert differential flip-flop outputs to single-ended multi-phase clocks. To avoid erratic or multiple oscillation and overtones, fewer than eight and preferably four differential delay stages are used. The delay stages are arranged in a twisted-ring with the differential outputs of the last delay stage crossed over and fed back to the differential inputs of the first delay stage. Tail currents of the delay stages can be adjusted by a voltage generated by a PLL loop. The differential toggle flip-flops allow for many taps or clock phases to be generated from the few delay stages.

Abstract: A differential amplifier has a boosted sink current that is turned on by a pulse generator when the output is driven low. This boosted sink current quickly lowers the output to the voltage-output-low VOL level. After the pulse ends, the sink current ends and power is reduced to a lower standby level. A differential pair of switches receives the true and complement data. One switch is closed when the data is true, connecting a current source that sets the standby voltage-output-high VOH level. The other switch is closed when the complement data is high, connecting another current source that sets the standby VOL level. A second differential amplifier with reversed true and complement data drives a complement output for a differential signaling transmitter, such as for a pseudo-emitter-coupled logic (PECL) driver.

Abstract: A voltage translator programmably converts signals generated from a first power-supply voltage to a second power-supply voltage, or vice-versa. In response to control signals, bootstrap switches connect either the first or second power supply to a first internal supply, and either the second or first power supply to a second internal supply. A pair of inverters are sourced by the first power supply and generate true and complement data signals. Cross-coupled p-channel load transistors are sourced by the second internal power supply. A differential pair of n-channel transistors have drains connected to the drains of the load transistors, and gates driven by the true and complement data signals. The bootstrap switches use boosted signals above the power-supply voltages to programmably connect full-voltage power supplies to the internal supplies.

Abstract: A large pull-down voltage-output-low VOL transistor is placed in parallel with a smaller pull-down switching transistor. The smaller switching pull-down transistor is turned on during switching. Once switching has nearly completed, the larger pull-down VOL transistor is turned on to provide a current sink for maintaining a VOL close to ground. Switching current is limited by the smaller switching pull-down transistor, while a large static sink current is provided by the VOL transistor to meet VOL requirements. The gate of the VOL transistor is controlled by p-channel and n-channel data transistors that are controlled by the data input, and p-channel and n-channel feedback transistors with gates connected to the buffer output. An upper n-channel transistor provides current to an intermediate node at the drain of the p-channel feedback transistor, keeping it near an intermediate voltage.

Abstract: An active terminating circuit has n-channel and p-channel sensing transistors with gates connected to a transmission line. The sensing transistors drive a back node connected to a pair of capacitors. One capacitor drives a p-gate node coupled to a gate of a p-channel clamping transistor, while the other capacitor drives an n-gate node coupled to a gate of an n-channel clamping transistor. The drains of the clamping transistors are connected to the transmission line. Resistors pull the p-gate node to the power-supply voltage and pull the n-gate node to ground when no transitions occur on the transmission line to achieve zero standby power. When a transition is detected, it is inverted and coupled through the capacitors to the p-gate and n-gate nodes. The p-channel clamping transistor is turned on for rising transitions, while the n-channel clamping transistor is turned on for falling transitions. Limiting transistors limit gate-node swings.

Abstract: A clock driver for an integrated circuit reduces electro-magnetic interference (EMI) induced in nearby metal traces yet also reduces jitter due to noise at the switching threshold. A weak driver using small n-channel and p-channel transistors initially drives the clock line. Then a pulse generator produces a short pulse to a gate of a large driver transistor. The large driver transistor is pulsed on for a very short period of time. The large driver transistor is turned off by the end of the pulse before the clock line completes its transition. The weak driver then finishes the clock-line transition. Since only the weak driver is on during the start and end of the transition, a slow voltage-slew rate occurs at the beginning and end of the transition. The large driver transistor is on only in the middle of the transition, producing a fast voltage-slew rate in the middle. A triple-slope waveform results.

Abstract: An output buffer has a large pull-down driver transistor that draws a large current. The large driver transistor is pulsed off when a neighboring pin is switching, reducing noise and ground bounce. Pulse signals and a local enable are NOR'ed together to drive the gate of the large driver. The pulse signals are routed to many output buffers in a chip. Each data input is sent to a detector slice. The detector slice normally generates a pulse when the data input changes. These pulses from individual detector slices are combined into the pulse signals. The detector slice also receives a control signal from a control input to the chip. The control input enables a latch or flip-flop in the data path from the data input to the output buffer. When the latch is enabled, changes in the data input do not immediately affect the output buffer, but must wait for a clock edge. The control input that enables the latch also controls a mux in each detector slice.

Abstract: A clock generator has a duty cycle correction circuit that adjusts the duty cycle to 50%. A modulator is an inverter with extra source-limiting transistors in series to the power and ground supplies. A control voltage of about Vcc/2 is applied to the source-limiting transistors, causing them to operate in the linear region with limited current. A slow-slew output from the modulator is buffered by a driver. The driver output is filtered by a linear detector with a series resistor and input capacitor. The detector output is compared to a reference voltage of Vcc/2 by an error amp. The error amp generates the control voltage fed back to the modulator. An output capacitor creates a dominant pole with the error amp to ensure stability. A variable-threshold gate can be added between the driver output and the detector to separately adjust the measurement threshold voltage from the reference voltage to the error amp.

Abstract: Both buses connected to a bus switch are protected from undershoots. A bus switch transistor is an n-channel metal-oxide-semiconductor (MOS) with its source connected to a first bus and its drain connected to a second bus. An enable gate drives the gate node of the bus switch transistor high to enable or low to disable. Undershoot sensing circuits are attached to the first and second bus. When a low-going transition is detected by an undershoot sensing circuit, an n-channel connecting transistor is turned on, connecting the bus with the low-going transition to the gate node through a grounded-gate n-channel transistor. If an undershoot occurs, it is coupled to the gate node. Since both the gate and source of the bus switch transistor are coupled to the undershoot, the gate-to-source voltage never reaches the transistor threshold and the bus switch transistor remains off.

Abstract: A power-up-reset circuit draws zero standby current. Rather than use a voltage divider that always draws current, a capacitive-pullup divider is used as the first stage. The capacitive-pullup divider has a capacitor to power (Vcc) and n-channel series transistors to ground. A sensing node between the capacitor and n-channel series transistors is initially pulled high to Vcc as Vcc is ramped up. The n-channel transistors remain off until Vcc reaches about 1.5 volts. Then the n-channel transistors pull the sensing node quickly to ground, ending the reset pulse. The second stage has a capacitor to ground that initially holds a threshold node low. A p-channel transistor has a gate connected to the sensing node and charges up the capacitor when the sensing node falls to ground. A third stage is triggered to change state as the capacitor is charged up by the p-channel transistor. Then a Schmidt trigger toggles, as do downstream inverter stages.

Abstract: A low-voltage differential signaling (LVDS) output buffer has an improved eye pattern. The LVDS buffer has two parallel stages. A primary stage generates enough current to generate a first voltage drop across a load resistor. At higher frequencies, parasitic capacitive coupling reduces this first voltage drop, closing the eye pattern. A boost stage generates an additional boost current through the load resistor, adding to the voltage drop and opening the eye pattern. The boost stage is coupled to the outputs by link transistors that are enabled by a pre-emphasis signal generated by resetable pulse generators. When outputs switch, the pre-emphasis signal pulses the link transistors on, adding the boost current. At high frequencies, the pulse generators are reset before the pre-emphasis signal ends. The boost current is continuously added at high frequencies, but at low frequencies the boost current only occurs during the pre-emphasis period after outputs switch.

Abstract: A fail-safe circuit for a differential receiver can tolerate high common-mode voltages. An output from a differential amplifier that receives a V+ and a V− differential signal can be blocked by a NOR gate when the fail-safe condition is detected, such as when the V+, V− lines are open. Pullup resistors pull V+, V− to Vcc when an open failure occurs. A pair of comparators receive a reference voltage on the non-inverting input. Once comparator outputs a high when the V+ line is above the reference voltage, and the other comparator outputs a high when the V− line is above the reference voltage. When both V+ and V− are above the reference voltage, the NOR gate blocks the output from the differential amplifier, providing a fail-safe. Since the reference voltage is very close to Vcc, a high common-mode bias can exist on V+, V− without falsely activating the fail-safe circuit.

Abstract: An amplifier designed from CMOS transistors provides a high current output, despite having a unity-gain configuration. A push-pull output stage drives the output using a p-channel pull-up transistor and an n-channel pull-down transistor. The pull-down transistor's gate is driven by an output from an inverting differential amplifier, that has one differential transistor gate driven by an input voltage and the other driven by the output voltage. A second differential amplifier is configured as a non-inverting differential amplifier, with one differential transistor gate driven by the input voltage and the other driven by the output voltage. The second differential amplifier drives an n-channel gate of an inverting stage, and the output of the inverting stage drives the p-channel pull-up transistor's gate.