Abstract: A circuit for measuring timing uncertainty in a clocked digital path and in particular, the number of logic stages completed in any clock cycle. A local clock buffer receives a global clock and provides a complementary pair of local clocks. A first local (launch) clock is an input to a delay line, e.g., 3 clock cycles worth of series connected inverters. Delay line taps (inverter outputs) are inputs to a register that is clocked by the complementary clock pair to capture progression of the launch clock through the delay line and identify any variation (e.g., from jitter, VDD noise) in that progression. Global clock skew and across chip gate length variation can be measured by cross coupling launch clocks from a pair of such clock buffers and selectively passing the local and remote launch clocks to the respective delay lines.

Abstract: Delay lines include an adjustable delay cell that adjusts a speed at which an input signal to the adjustable delay cell is transmitted through the adjustable delay cell responsive to a control signal. A plurality of set delay cells are coupled in series with the adjustable delay cell that delay transmission through the set delay cells of an input signal to the respective set delay cells an amount that does not vary responsive to the control signal. Delay cells that have an adjustable delay time are also provided.

Abstract: This disclosure relates to a cell-placeable variable-frequency digitally controlled oscillator (DCO) that consumes approximately the same current in a fast process corner as in the case of a slow process corner. By modulating the effective channel length of transistors in inverters, a fast process DCO may be slowed down to a desired frequency at nearly the same current consumption as that of a slow process DCO.

Abstract: A delay circuit includes a first delay line circuit having a plurality of stages of delay units, a second delay line circuit having a plurality of stages of delay units, a plurality of transfer circuits provided in association with respective stages of the delay units of the first delay line circuit, the transfer circuits controlling the transfer of the outputs of the delay units of the first delay line circuit to associated stages of the delay units of the second delay line circuit. The delay units of respective stages of the first delay line circuit inverting input signals. Each stage delay unit of the second delay line circuit includes a logic circuit receiving an output signal of the transfer circuit associated with the delay unit in question and an output signal of a preceding stage to send an output signal to a following stage. The duty ratio is rendered variable by independently selecting the rising edge of the input signal and a propagation path of the falling edge.

Abstract: A system and method for asynchronous triggering in a waveform generator comprising a DAC sample clock for generating DAC sample clock signal. The system includes a sequencer clock for generating a sequencer clock signal having a frequency of 1/N of the DAC sample clock. The system also includes an output data generator having I outputs to receive a waveform data stream of samples shifted into the data generator at the rate of the sequencer clock signal. An output multiplexer coupled receives samples from each of the I outputs of the output data generator and outputs the samples as a multiplexed data stream to the DAC. A triggering system receives an asynchronous trigger and splits the signal into an integer multiple M trigger inputs, each trigger input delayed by a DAC sample clock cycle. A shift controller determines a trigger position based on the trigger inputs and shifts a different waveform data stream into the data generator in accordance with the trigger position.

Abstract: There is provided a semiconductor circuit including three or more nodes at least including one input node and one output node, plural paths which are connected between the three or more nodes and whose signal propagation directions between the nodes are regulated, a signal propagation time regulator for regulating a signal propagation time of each of the paths, an input unit for inputting a predetermined input signal to the input node, and a detector for detecting a time required for the input signal to propagate through the paths and arrive at the output node.

Abstract: A delay control circuit includes a first delay unit, a signal regulation unit, a selector and a second delay unit. The first delay unit is used for delaying an input signal and generates a delayed input signal. The signal regulation unit is coupled to the first delay unit and outputs a rising edge delay signal and a falling edge delay signal according to the input signal and the delayed input signal. The selector is coupled with the signal regulation unit and outputs one of rising edge delay signal and falling edge delay signal according to the control signal. The second delay unit is coupled to the selector for delaying the output of the selector and outputting an output signal.

Abstract: Some embodiments include a delay locked circuit having multiple paths. A first path measures a timing of a first clock signal during a measurement. A second path generates a second clock signal based on the first clock signal. The delay locked circuit periodically performs the measurement to adjust a timing relationship between the first and second clock signals. The time interval between one measurement and the next measurement is unequal to the cycle time of the first clock signal. Additional embodiments are disclosed.

Abstract: A device for setting a clock delay is proposed, wherein delayed output clock signals are generated with the aid of delaying means by delaying an input clock signal. The delaying means are configured to provide several differently delayed clock signals simultaneously. The device is configured to generate the at least one output clock signal depending on the differently delayed clock signals with a settable phase relationship to the non-delayed input clock signal, wherein the phase relationship is settable independently of the delay provided by the delaying means. It is particularly provided that the phase relationship between the delayed output clock signal and the non-delayed input clock signal is automatically controlled to a desired phase relationship independently of the delay supplied by the delaying means.

Abstract: A device includes a first circuit having rows and columns of delay cells to generate delayed signals based on an input signal. The delayed signals are selectable and have a different delay from one another with respect to the input signal. The device is programmable based on a delay code. Different values of the delay code allow the device to select different delayed signals. The device may select one of the delayed signals from the first circuit for use as a timing signal in a second circuit of the device. The device may also use the delayed signals from the first circuit to evaluate a clock and data recovery circuit. In an embodiment, the circuits may be located on a single die.

Abstract: A quality assurance integrated circuit for a print controller is provided. The IC has a memory, a system clock having a ring oscillator for generating a clock signal, clock trim circuitry for trimming the clock signal generated by the system clock and a processor. The processor is arranged to, in response to receiving an external signal, determine the number of cycles of the clock or external signal during a predetermined number of cycles of the external or clock signal, respectively and to output the determined number of cycles to an external circuit, and, in response to receiving a trim value based on the determined number of cycles from the external circuit, store the trim value in the memory and control the clock trim circuitry to trim the frequency of the clock signal generated by the ring oscillator using the trim value.

Abstract: The present invention relates generally to a buffer of a drive Integrated Circuit (IC) and, more particularly, to a buffer of a drive IC for driving a spatial light modulator that can meet a desired dynamic slew rate characteristic by controlling current that affects a slew rate.

Abstract: A semiconductor integrated circuit includes a integration circuit which has a first integrating portion and a second integrating portion. The semiconductor integrated circuit also includes a data input portion, data processing portion and data output portion. A clock signal is inverted by an input buffer and applied to a NAND gate together with a mask signal. When the signal from the NAND gate rises, the signal of the second integrating portion falls after a delay time due to the integration circuit. The signal from the NAND gate is applied together with the signal from the second integrating portion to a second NAND gate, and the signal from the second NAND gate is fixed at “L” during the period from the time of the rise of the clock signal for the duration of the delay time of the integration circuit. The signal from the second NAND gate is delayed by a third integrating portion and a delay time of the third integrating portion is added by an AND gate to generate a mask signal.

Abstract: A delay circuit includes a first delay line circuit having a plurality of stages of delay units, a second delay line circuit having a plurality of stages of delay units, a plurality of transfer circuits provided in association with respective stages of the delay units of the first delay line circuit, the transfer circuits controlling the transfer of the outputs of the delay units of the first delay line circuit to associated stages of the delay units of the second delay line circuit. The delay units of respective stages of the first delay line circuit inverting input signals. Each stage delay unit of the second delay line circuit includes a logic circuit receiving an output signal of the transfer circuit associated with the delay unit in question and an output signal of a preceding stage to send an output signal to a following stage. The duty ratio is rendered variable by independently selecting the rising edge of the input signal and a propagation path of the falling edge.

Abstract: A delay line including analog delay elements each having a selectively adjusted coarse and fine delay portion is described. The coarse delay portion receives an input clock signal and generates a ramp signal having a slope based on a predetermined coarse delay setting. The fine delay portion generates a threshold voltage based on a predetermined fine delay setting. A comparator compares the coarse delay ramp signal voltage with the fine delay threshold voltage and generates an output clock signal when the ramp signal voltage surpasses the fine delay threshold voltage. The coarse delay is linearly adjustable based on a 32-bit binary input signal and the fine delay is binary-weight adjusted based on a 5-bit binary input signal. Both the coarse and fine delay portions are controlled by delay line control circuitry which compares a feedback version of the output clock signal with the input clock signal and provides control signals to increment or decrement coarse and fine delay in the delay line.

Abstract: A delay locked circuit has multiple paths for receiving an external signal. One path measures a timing of the external signal during a measurement. Another path generates an internal signal based on the external signal. The delay locked circuit periodically performs the measurement to keep the external and internal signals synchronized. The time interval between one measurement and the next measurement is unequal to the cycle time of the external signal.

Abstract: By forming adjacent wiring 4 adjacent to signal wiring 3 and using a control circuit 13 comprising a 2-input NAND 20 circuit or the like to input a signal S4 corresponding to a signal S3 in the signal wiring 3 to the adjacent wiring 4, it is made possible to change the delay of the signal S3 in the signal wiring 3 in several picoseconds, by using crosstalk with the signal S4 in the signal wiring 4.The inventive delay control circuit device can be provided by simply adding adjacent wiring 4 and a control circuit 13 to signal wiring 3. This implements a delay control circuit device for semiconductor integrated circuits that is capable of controlling a signal delay in several picoseconds without increasing the circuit scale.

Abstract: A delay line for a digital clock manager includes a tap delay structure and a trim delay structure. The trim delay structure includes a first buffer coupled to receive a clock signal from the tap delay structure, and in response, provide a delayed clock signal to a set of clock lines. The trim delay structure also includes a capacitive trim unit having a plurality of capacitive trim elements tapped off the set of clock lines. The capacitive trim elements are selectively enabled or disabled, thereby introducing additional delay to the delayed clock signal on the set of clock lines. Each capacitive trim element can include a transmission gate structure, which is turned on to introduce significant junction capacitance to the set of clock lines. The trim delay structure can also include a second buffer adapted to buffer the delayed clock signal on the set of clock lines.

Abstract: A method and apparatus for a frequency-based slope-adjustment circuit block are described herein.

Abstract: A delay circuit includes a first delay line circuit having a plurality of stages of delay units, a second delay line circuit having a plurality of stages of delay units, a plurality of transfer circuits provided in association with respective stages of the delay units of the first delay line circuit, the transfer circuits controlling the transfer of the outputs of the delay units of the first delay line circuit to associated stages of the delay units of the second delay line circuit. The delay units of respective stages of the first delay line circuit inverting input signals. Each stage delay unit of the second delay line circuit includes a logic circuit receiving an output signal of the transfer circuit associated with the delay unit in question and an output signal of a preceding stage to send an output signal to a following stage. The duty ratio is rendered variable by independently selecting the rising edge of the input signal and a propagation path of the falling edge.

Abstract: As devices are often different in the characteristics from one another, semiconductor chips based on the devices have discrepancies in the performance. A semiconductor device having a semiconductor switching element and a drive controlling means (1) for generating from input signals (A) and (B) drive signals (a) and (b) to control the action of the semiconductor switching element is provided comprising a characteristic compensating means (2) for generating from a characteristic compensation input signal a compensation signal to eliminate variations in the transmission delay time of the drive controlling means (1).

Abstract: In order to generate an output signal delayed compared to an input signal and with a defined mark-to-space ratio, it is useful to produce at least first and second intermediate signals delayed differently with respect to the input signal and to combine them to form the output signal so that a rising (or negative) edge of the first intermediate signal determines a rising edge of the output signal, and a rising (or negative) edge of the second intermediate signal determines a falling edge of the output signal. In particular a plurality of successive versions of an input timing signal delayed by an equal amount can be generated with a mark-to-space ratio of 50%.

Abstract: A method of transmitting adjacent signals is disclosed. Sensing is performed on signals in the group and adjacent signals are either switched or delayed if the adjacent signals are switching at the same time. The method is used in networks where coupling and capacitance effects are possible.

Abstract: A delay circuit. The delay circuit includes a first circuit, a falling edge delay circuit and a rising edge delay circuit. The first circuit includes a circuit input for receiving a reference signal and a circuit output for outputting a delayed signal. The falling edge delay circuit is coupled to the first circuit to control delay of a falling edge of the reference signal. The rising edge delay circuit is coupled to the first circuit to control delay of a rising edge of the reference signal.

Abstract: A data transmission error reduction circuit is formed including a delay circuit, a detection circuit and a control circuit. In one embodiment, the delay circuit includes n delay element and multiplexor pairs, selectively employable to apply an aggregate amount of time delay to a data signal. The detection circuit includes circuit elements to detect a critical reference time distance between a reference point of a data signal and at least a selected edge of a clock signal being smaller than a desired threshold. The control circuit includes circuit elements to dynamically control the aggregate amount of time delay applied by the delay circuit based at least in part on the detection of the detection circuit. In one application, m units of the data transmission error reduction circuit are correspondingly employed to reduce data transmission errors on m high speed parallel data signals of a data interface.

Abstract: A counter-controlled delay line for delaying signals having a wide range of possible frequencies is described. The counter-controlled delay line receives an input clock and produces a delayed output clock based on a delay select control signal. The delay select control signal includes three granularities of delay: a coarse grain, medium grain, and fine grain. The coarse grain delay is provided by a counter. The medium grain delay is provided by a sequential starter circuit coupled to an oscillator. The fine grain delay is provided by a trim unit.

Abstract: A method and apparatus for updating the control signal received by a delay chain in a DDR application. A register is used to regulate the control signal to the delay chain. The register only updates the signal at the delay chain when a signal is not passing through the delay chain. Additionally, the present invention is directed to a delay circuit that uses a plurality of PMOS and NMOS transistors connected in parallel to each other and to an inverter that provides the desired delay. The delay provided is achieved by sequentially turning off/on a series of the NMOS/PMOS transistor pairs.

Abstract: A timing circuit independently controls placement of the positive and negative edges of a periodic signal. This signal may then be used to control a wide variety of integrated circuit applications. The timing circuit includes separate programmable delay lines and a signal processor. Each delay line delays an input clock signal by a different increment of time. The signal processor then generates a timing signal from the clock signal, where the timing signal has a first edge controlled by the first delayed clock signal and a second edge controlled by the second delayed clock signal. The edges may be controlled so that the timing signal assumes different logical values for different amounts of time, thereby customizing the signal to any application. An example of one application includes using the timing signal control switching in a DC-DC converter.

Abstract: A jitter inducing circuit receives a reference pulse train and induces desired amounts of jitter to the rising and/or falling edges of the pulses. First and second delay blocks 16 and 18 alternately delay the selected edge or edges of the provided reference pulse train interval by preset delay times for every interval. A signal composer 46 composes the outputs of the first and second delay blocks 16 and 18. A delay time setup circuit controls the delay times of the delay blocks 16 and 18. The delay times may change for each interval as a function of time so as to trace a desired function such as a sinusoidal or triangular function.

Abstract: The precharge circuit includes circuitry for initiating charging of a precharge pulse at a first edge of a first clock-like signal. The precharge circuit also includes circuitry for ending the charging of the precharge pulse after a time period that is longer of a preset delay period and a time period designated by a second edge of the second clock-like signal.

Abstract: A circuit is provided that aligns the phase of a delay signal with an input clock signal. The circuit functions as a phase locked loop (PLL) in a first state of operation and as a delay locked loop (DLL) in a second state of operation. An adjustable delay circuit generates the delay signal. A phase detector compares the input clock signal to the delay signal to generate a phase detection signal. The adjustable delay circuit adjusts the phase of the delay signal in response to the phase detection signal. A multiplexer couples the delay signal back to the input of the adjustable delay circuit using a feedback loop in the first state of operation. The multiplexer couples the input clock signal to the input of the adjustable delay circuit in the second state of operation.

Abstract: A tuning circuit comprising a first reactance, a second reactance and a insulated gate field effect transistor having a gate arranged to receive a control signal. The first reactance is connected between the source of the field effect transistor and a first node. The second reactance has the same value as the first reactance and is connected between the drain of the field effect transistor and a second node. The first and second nodes are arranged so as to experience a balanced ac signal. Turning the field effect transistor on has the effect of making the first and second reactances effective in the circuit and vice versa.

Abstract: The memory device of the invention outputs the read data in a time starting from the rising edge of the external clock that is shorter than that of other known devices, because the output buffer has an array of master-slave pairs of flip-flops synchronized by respective timing signals derived from the internal clock signal. The array receives data from the state machine through the second internal bus and provides the data to be output to the output stage of the buffer enabled by the state machine. A logic circuit generates timing signals for the master-slave flip-flops, respectively as logic NAND and logic AND of the internal clock signal and of an enabling signal of the output stage of the buffer generated by the state machine. Moreover, the memory device includes a circuit, synchronized by the internal clock signal, that introduces a delay of the enabling signal of the output stage of the buffer equivalent to a period of the internal clock signal.

Abstract: A method and system for providing variable edge control of pulse waveforms is provided. A positive edge DAC number is set so that the positive edge time of a first pulse waveform of some amplitude is substantially equal to some initial edge time. Similarly, a second positive edge DAC number associated with a second pulse waveform of different amplitude is set so that the positive edge time of the second pulse waveform also equals the initial edge time. Positive gain and offset factors are then generated so that a third positive edge DAC number associated with any pulse waveform may be calculated so that a desired positive edge time of that waveform is produced. Negative edge DAC numbers may be calculated in a similar manner so that the positive and negative edge times of a pulse waveform may be balanced, or more efficient methods may be used.

Abstract: For generating a delay signal, a series of source signals based on the same high frequency signal are first provided. Every adjacent two of the source signals have a phase difference of a certain clock unit therebetween. A first and a second output signals are then generated on the basis of the plurality of source signals at a first and a second time points selected as desired. The first and the second output signals are processed by a logic operation to obtain the accurate and adjustable delay signal. For obtaining the first and the second output signals, the source signals are duplicated at first, and then respectively processed in response to respective clock signals.

Abstract: A method and device program a dual edge programmable delay unit, that responds to an input signal with a rise time and a fall time, includes a buffer which receives the input signal and provides an output signal with programmed variable delays between the rise and fall times of the output signal. Programmable control sources (PCS) provide separate control inputs to a buffer. The FTPCS charges a capacitor in the buffer when the input signal changes from high to low to adjust time delay before the fall of the buffer output signal. The RTPCS discharges the capacitor in the buffer when the input signal changes from low to high to adjust time delay before the rise of the buffer output signal.

Abstract: A duty-cycle adjustable buffer and a method for operating such buffer can be applied to a clock tree circuit for providing an adjustable duty cycle. The duty-cycle adjustable buffer includes a first inverter and a second inverter connected with each other in series. Each of the first inverter and the second inverter includes a plurality of controlled current charging paths and a plurality of controlled current discharging paths, wherein at least one controlled current charging path and at least one controlled current discharging path of the first inverter and the second inverter are conducted. The timing of the rising edge and falling edge of a clock signal is dynamically adjusted so as to dynamically altering the duty cycle of the clock signal.

Abstract: The present invention accepts timing and clock signals with a desired frequency and undesired duty cycle CLKIN, and outputs a clock signal CLKOUT with the desired frequency and desired duty cycle. If the clock signal is known to have a duty cycle of greater than 50%, one exemplary embodiment of the present invention delays the rising edge of the clock signal so as to produce a clock signal with a 50% duty cycle. One exemplary embodiment of the present invention comprises a charge pump integrator (102) configured in a feedback loop, the output of the charge pump integrator (102) operable as a controlling node to delay inverter (115). If the clock signal CLKIN at the input of the circuit has a duty cycle of greater than 50%, then the charge pump integrator (102) will, through PBIAS, cause delay inverter 115 to delay of the rising edge of CLKIN through delay inverter (115). The charge pump integrator, through PBIAS, drives the duty cycle of the clock signal towards 50%.

Abstract: A clock pulse generator for generating at least two clocked pulse signals from a global clock signal is provided. The clock pulse generator includes at least one input for receiving a clock signal having a rising and a falling edge and a mechanism for selectably delaying a rising edge of a pulse signal synchronized to the falling edge of the clock signal. The clock pulse generator further includes a first selectable duration pulse synchronized to the rising edge of the clock signal and a second selectable duration pulse synchronized to the selectably delayed rising edge. The clock pulse generator also includes a glitch avoidance circuit to remove glitches in the clock signal before it is used.

Abstract: A system for coordinating the timing of a data strobe with data supplied by a memory module to the memory controller read data FIFO of a processor-based system, providing multiple calibration modes. A calibration PDL (programmable delay line) is used to reiteratively test the time taken for a test data strobe to traverse a portion of the memory controller circuit, and to generate a calibration value based upon the time taken. The calibration procedure may be initiated in any one of several modes, including: according to a predetermined schedule; implemented in software; in response to changes in environmental factors such as temperature or voltages sampled at one or more locations; in response to a software-driven trigger; or in response to a user-initiated trigger, communicated to a system of the invention either by input via a user interface to the processor-based system or by a software command.

Abstract: A timing generating apparatus for generating a timing signal which changes at desired timing includes a first waveform generating unit for generating a first basic waveform whose value changes only at desired change timing of a basic frequency, a PLL for generating a sampling clock whose frequency is an integer multiple of the basic frequency and whose phase is more stable than the basic waveform based on a PLL input signal whose frequency is an integer multiple of the basic frequency or a reciprocal of an integer multiple thereof, a first sampling unit for outputting a first sampling signal which results from sampling the first basic waveform with the sampling clock, and an output unit for outputting the timing signal based on the first sampling signal.

Abstract: Disclosed is a method and apparatus for variably and independently delaying the rising and falling edges of a digital waveform including a dual polarity output buffer, a first delay circuit, a second delay circuit and a recombination circuit. The dual polarity output buffer outputs a first signal that is a substantial replica of the input signal and a second signal that is an inversion of the input signal. The first delay circuit is connected to the dual polarity output buffer and generates a first time delay in the rising edges of the first, non-inverted signal. The second delay circuit is also connected to the dual polarity output buffer and generates a second time delay in the rising edges of the second, inverted signal. The recombination circuit is connected to both the first delay circuit and the second delay circuit and combines the outputs thereof to generate a composite output signal representing the input signal with both the rising edges thereof and the falling edges thereof delayed independently.

Abstract: Disclosed is a timing control circuit for semiconductor device capable of controlling timing of internal signal after packaging by using a fuse. The disclosed comprises: a signal delay unit comprising delay elements and for delaying externally received signal for a predetermined time and outputting the result; and a fuse unit capable of determining whether to enable or disable after packaging the semiconductor device and then, determining whether to delay the signal by the delay element or not according to whether it is enabled or not, thereby controlling delay time of signal by the signal delay unit.

Abstract: A delay circuit has an input node receives an input pulsed signal. A buffer transfers the input signal to a floating node. A detector outputs to an output node an output voltage that has a first level, if the voltage at the floating node is below a threshold, and a second level otherwise. Two similar branches are used, one for controlling delays in the rising transitions and one for controlling delays in the falling transitions. For each branch, a reference terminal carries a reference voltage for biasing the floating node. A capacitor and a switch are coupled between the reference terminal and the floating node. The switch opens and closes responsive to the output voltage. When it opens, it shorts out the capacitor. An optional phase detector and delay code generator may be in a feedback arrangement, for continuously adjusting the reference voltages.

Abstract: A delay locked circuit has multiple paths for receiving an external signal. One path measures a timing of the external signal during a measurement. Another path generates an internal signal based on the external signal. The delay locked circuit periodically performs the measurement to keep the external and internal signals synchronized. The time interval between one measurement and the next measurement is unequal to the cycle time of the external signal.

Abstract: A delay locked loop having improved synchronization times has a variably adjustable delay line which accepts two incoming clock pulses. As each pulse propagates through the delay line an edge of the pulse toggles or retoggles a shift bit corresponding to a delay element. When the first pulse reaches the end of the delay line, the status of the shift bits is frozen, and a starting point for a synchronization sequence begins at the transition point between toggled and retoggled shift bits.

Abstract: A delay adjustment circuit for a delay locked loop, comprises a delay rough adjustment circuit unit (to which input clock signal CLK-IN, and delay control signals A1 to A6 are transmitted) for selectively obtaining outputs of roughly adjusted delays A and B of two systems having a delay difference indicating a maximum delay value of fine interval delay quantity adjustment from selected ones of selection circuits S1, S3 and S5 of an odd-number stage and selection circuits S2, S4 and S6 of an even-number stage connected to delay elements D1 to D3. Furthermore, a delay fine adjustment circuit unit (to which delay control signals B1 to B4, and enable signal ENABLE are transmitted) including delay elements FA and FB for receiving outputs of roughly adjusted delays A and B, and selectively carrying out fine interval delay quantity adjustments of the two systems by opposite operations.

Abstract: A controlled delay circuit has a first gate chain, and a second gate chain. The first gate chain is used to measure a time difference between a changeover point of a first control signal and a changeover point of a second control signal. The second gate chain, which receives third signals generated in the first gate chain and representing the time difference, is used to provide an appropriate delay time from an input to an output depending on the time difference. The controlled delay circuit is capable of properly controlling the timing of the control signal according to the period of the control signal.

Abstract: There is provided a semiconductor circuit including three or more nodes at least including one input node and one output node, plural paths which are connected between the three or more nodes and whose signal propagation directions between the nodes are regulated, a signal propagation time regulator for regulating a signal propagation time of each of the paths, an input unit for inputting a predetermined input signal to the input node, and a detector for detecting a time required for the input signal to propagate through the paths and arrive at the output node.

Abstract: A programmable delay circuit (100) maximizes processor bandwidth to external peripherals by eliminating wait state addition as the only way for satisfying timing requirements. Circuit (100) includes a programmable delay chain (102) connected to a hysteresis circuit (150). A processor control signal is fed into the programmable delay chain (102) which includes at least one switch (104-116) and at least one resistive element (118-126) connected together. A first feedback circuit (128) connects the output of the programmable delay chain (102) to the input (IN2) of the first embodiment (100) to keep the falling edge of the control signal the same without any significant added delay. The hysteresis circuit (150) which provides a stable signal connects to an output driver (180) for driving the processor control signal.