Abstract: A clock generator circuit generates a sequence of clock signals equally phased from each other from a master clock signal. The clock generator is formed by inner and outer delay-locked loops. The inner delay-locked loop includes a voltage controlled delay line that delays a reference clock applied to its input by a plurality of respective delays. Two of the clock signals in the sequence are applied to a phase detector so that the signals at the outputs of the delay line have predetermined phases relative to each other. The outer delay-locked loop is formed by a voltage controlled delay circuit that delays the command clock by a voltage controlled delay to provide the reference clock to the delay line of the inner delay-locked loop. The outer delay-locked loop also includes a phase detector that compares the command clock to one of the clock signals in the sequence generated by the delay line. The outer delay-locked loop thus locks one of the clock signals in the sequence to the command clock.

Abstract: A phase detector generates a phase dependent control signal according to the phase relationship between a first and second clock signal. The phase detector includes first and second phase detector circuits receiving the first and second clock signals and generating select signals having duty cycles corresponding to the phase relationship between the clock edges of the first and second clock signals. The phase detector also includes a charge pump that receives select signals from the phase detector circuits and produces an increasing or decreasing control signal when the first and second clock signals do not have the predetermined phase relationship, and a non-varying control signal when the first and second clock signals do have the predetermined phase relationship. The control signal may be used to adjust the delay value of a voltage-controlled delay circuit in order to adjust the phase relationship between the first and second clock signals to have a predetermined phase relationship.

Abstract: A phase detector generates a phase dependent control signal according to the phase relationship between a first and second clock signal. The phase detector includes first and second phase detector circuits receiving the first and second clock signals and generating select signals having duty cycles corresponding to the phase relationship between the clock edges of the first and second clock signals. The phase detector also includes a charge pump that receives select signals from the phase detector circuits and produces an increasing or decreasing control signal when the first and second clock signals do not have the predetermined phase relationship, and a non-varying control signal when the first and second clock signals do have the predetermined phase relationship. The control signal may be used to adjust the delay value of a voltage-controlled delay circuit in order to adjust the phase relationship between the first and second clock signals to have a predetermined phase relationship.

Abstract: A method and circuit control the value of generated voltage derived from a supply voltage as the value of the supply voltage varies, such as during burn-in of an integrated circuit. A voltage generation circuit includes a generator circuit that receives a supply voltage and has a reference node and develops an output voltage from the supply voltage, the output voltage having a value that is a function of a reference voltage applied on the reference node. A coupling circuit receives the supply voltage and operates in response to a voltage control signal to vary an electronic coupling of the supply voltage to the reference node to thereby adjust the value of the reference voltage. A voltage sensing circuit develops the voltage control signal that is applied to the coupling circuit in response to the reference voltage.

Abstract: A method and circuitry for a delay lock loop useful in synchronizing the accessing of a memory array with a system clock is disclosed. In a preferred embodiment, the delay lock loop includes a variable delay element. The delay of the variable delay element is initially set to a minimum delay value. The system clock is then frequency divided and sent to the variable delay element, the output of which will ultimately be used to access the memory array in a synchronized manner with the system clock. The frequency divided clock and the output of the variable delay element are input to a phase detector, which creates a control signal for adjusting the delay of the variable delay element. After the signals are determined to be locked by the phase detector, an undivided clock signal version of the clock signal is sent to the variable delay element, and a frequency divided version of the output of the variable delay element is sent to the phase detector in lieu of the previous output of the variable delay element.

Abstract: A method of forming a semiconductor package is provided. The method includes forming a leadframe wherein the conductors or leads of the leadframe extend from a first end to a second end such that a portion of each lead exhibits a generally arcuate shape. The first end may be coupled with a printed circuit board and the second end may be coupled with a semiconductor die. The generally arcuately shaped portion of the leads may include a portion which exhibits a constant radius. The generally arcuately shaped portion may also be formed from a plurality of conductor segments including, for example, at least one generally arcuately shaped segment. The semiconductor die and at least a portion of the leads may be encapsulated with an insulating material.

Abstract: A method and circuitry are provided for reducing duty cycle distortion in differential solid state delay lines. The differential solid state delay lines of the present invention include a plurality of delay line cells or stages connected in series. Because there may be asymmetry associated with the physical layout of each individual delay line cell or stage, it is advantageous to cross-connect every x stage of an n-stage delay line. Method, integrated circuit, electronic system and substrate embodiments including the differential solid state delay lines are also disclosed.

Abstract: A method and circuit adaptively adjust respective timing offsets of digital signals relative to a clock output along with the digital signals to enable a latch receiving the digital signals to store the signals responsive to the clock. A phase command for each digital signal is stored in an associated storage circuit and defines a timing offset between the corresponding digital signal and the clock. The clock is output along with each digital signal having the timing offset defined by the corresponding phase command and the digital signals are captured responsive to the clock and evaluated to determine if each digital signal was successfully captured. A phase adjustment command adjusts the value of each phase command. These operations are repeated for a plurality of phase adjustment commands until respective final phase commands allowing all digital signals to be successfully captured is determined and stored in the storage circuits.

Abstract: A method and circuit control the value of generated voltage derived from a supply voltage as the value of the supply voltage varies, such as during burn-in of an integrated circuit. A voltage generation circuit includes a generator circuit that receives a supply voltage and has a reference node and develops an output voltage from the supply voltage, the output voltage having a value that is a function of a reference voltage applied on the reference node. A coupling circuit receives the supply voltage and operates in response to a voltage control signal to vary an electronic coupling of the supply voltage to the reference node to thereby adjust the value of the reference voltage. A voltage sensing circuit develops the voltage control signal that is applied to the coupling circuit in response to the reference voltage.

Abstract: A system for controlling the duty cycle of a clock signal. The system includes a duty cycle adjustment circuit that receives an input clock signal and generates an output clock signal. The duty cycle adjustment circuit charges a capacitor when the input clock signal has a first logic level and discharges the capacitor with the input clock signal has a second logic level. The rates of charge and discharge are controlled by first and second control signals. When the capacitor has been charged to a first transition level, the output clock signal transitions to a first logic level, and when the capacitor has been discharged to a second transition level, the output clock signal transitions to a second logic level. The first and second control signals are supplied by a feedback circuit, which is implemented using an integrator circuit that receives the output clock signal and generates a feedback signal indicative of the duty cycle of the output clock signal.

Abstract: In digital circuits, such as memory circuits, it is sometimes necessary to delay one signal a precise amount of time relative a reference signal. One way to do this is to feed the reference signal to a delay-locked loop which generates a set of signals, each delayed a different amount relative the reference signal. However, as circuits get faster and faster, conventional delay-locked loops require the addition of extra interpolation circuitry to generate smaller delays, and thus consume considerable power and circuit space. Accordingly, the inventor devised a circuit which interlaces and synchronizes two delay-locked loops, each including a number of controllable delay elements linked in a chain. In one embodiment, the first loop produces a sequence of clock signals delayed an even number of delay periods relative a reference clock signal, and the second loop produces a sequence of clock signals delayed an odd number of delay periods relative the reference clock signal.

Abstract: A method and circuit control the value of generated voltage derived from a supply voltage as the value of the supply voltage varies, such as during burn-in of an integrated circuit. A voltage generation circuit includes a generator circuit that receives a supply voltage and has a reference node and develops an output voltage from the supply voltage, the output voltage having a value that is a function of a reference voltage applied on the reference node. A coupling circuit receives the supply voltage and operates in response to a voltage control signal to vary an electronic coupling of the supply voltage to the reference node to thereby adjust the value of the reference voltage. A voltage sensing circuit develops the voltage control signal that is applied to the coupling circuit in response to the reference voltage.

Abstract: A method and circuit control the value of generated voltage derived from a supply voltage as the value of the supply voltage varies, such as during burn-in of an integrated circuit. A voltage generation circuit includes a generator circuit that receives a supply voltage and has a reference node and develops an output voltage from the supply voltage, the output voltage having a value that is a function of a reference voltage applied on the reference node. A coupling circuit receives the supply voltage and operates in response to a voltage control signal to vary an electronic coupling of the supply voltage to the reference node to thereby adjust the value of the reference voltage. A voltage sensing circuit develops the voltage control signal that is applied to the coupling circuit in response to the reference voltage.

Abstract: A system for controlling the duty cycle of a clock signal. The system includes a duty cycle adjustment circuit that receives an input clock signal and generates an output clock signal. The duty cycle adjustment circuit charges a capacitor when the input clock signal has a first logic level and discharges the capacitor with the input clock signal has a second logic level. The rates of charge and discharge are controlled by first and second control signals. When the capacitor has been charged to a first transition level, the output clock signal transitions to a first logic level, and when the capacitor has been discharged to a second transition level, the output clock signal transitions to a second logic level. The first and second control signals are supplied by a feedback circuit, which is implemented using an integrator circuit that receives the output clock signal and generates a feedback signal indicative of the duty cycle of the output clock signal.

Abstract: A method and circuit adaptively adjust respective timing offsets of digital signals relative to a clock output along with the digital signals to enable a latch receiving the digital signals to store the signals responsive to the clock. A phase command for each digital signal is stored in an associated storage circuit and defines a timing offset between the corresponding digital signal and the clock. The clock is output along with each digital signal having the timing offset defined by the corresponding phase command and the digital signals are captured responsive to the clock and evaluated to determine if each digital signal was successfully captured. A phase adjustment command adjusts the value of each phase command. These operations are repeated for a plurality of phase adjustment commands until respective final phase commands allowing all digital signals to be successfully captured is determined and stored in the storage circuits.

Abstract: A method and circuitry for a delay lock loop useful in synchronizing the accessing of a memory array with a system clock is disclosed. In a preferred embodiment, the delay lock loop includes a variable delay element. The delay of the variable delay element is initially set to a minimum delay value. The system clock is then frequency divided and sent to the variable delay element, the output of which will ultimately be used to access the memory array in a synchronized manner with the system clock. The frequency divided clock and the output of the variable delay element are input to a phase detector, which creates a control signal for adjusting the delay of the variable delay element. After the signals are determined to be locked by the phase detector, an undivided clock signal version of the clock signal is sent to the variable delay element, and a frequency divided version of the output of the variable delay element is sent to the phase detector in lieu of the previous output of the variable delay element.

Abstract: A method and circuit control the value of generated voltage derived from a supply voltage as the value of the supply voltage varies, such as during burn-in of an integrated circuit. A voltage generation circuit includes a generator circuit that receives a supply voltage and has a reference node and develops an output voltage from the supply voltage, the output voltage having a value that is a function of a reference voltage applied on the reference node. A coupling circuit receives the supply voltage and operates in response to a voltage control signal to vary an electronic coupling of the supply voltage to the reference node to thereby adjust the value of the reference voltage. A voltage sensing circuit develops the voltage control signal that is applied to the coupling circuit in response to the reference voltage.

Abstract: A method and circuitry for a delay lock loop useful in synchronizing the accessing of a memory array with a system clock is disclosed. In a preferred embodiment, the delay lock loop includes a variable delay element. The delay of the variable delay element is initially set to a minimum delay value. The system clock is then frequency divided and sent to the variable delay element, the output of which will ultimately be used to access the memory array in a synchronized manner with the system clock. The frequency divided clock and the output of the variable delay element are input to a phase detector, which creates a control signal for adjusting the delay of the variable delay element. After the signals are determined to be locked by the phase detector, an undivided clock signal version of the clock signal is sent to the variable delay element, and a frequency divided version of the output of the variable delay element is sent to the phase detector in lieu of the previous output of the variable delay element.

Abstract: A method and circuit control the value of generated voltage derived from a supply voltage as the value of the supply voltage varies, such as during burn-in of an integrated circuit. A voltage generation circuit includes a generator circuit that receives a supply voltage and has a reference node and develops an output voltage from the supply voltage, the output voltage having a value that is a function of a reference voltage applied on the reference node. A coupling circuit receives the supply voltage and operates in response to a voltage control signal to vary an electronic coupling of the supply voltage to the reference node to thereby adjust the value of the reference voltage. A voltage sensing circuit develops the voltage control signal that is applied to the coupling circuit in response to the reference voltage.

Abstract: A method and circuit control the value of generated voltage derived from a supply voltage as the value of the supply voltage varies, such as during burn-in of an integrated circuit. A voltage generation circuit includes a generator circuit that receives a supply voltage and has a reference node and develops an output voltage from the supply voltage, the output voltage having a value that is a function of a reference voltage applied on the reference node. A coupling circuit receives the supply voltage and operates in response to a voltage control signal to vary an electronic coupling of the supply voltage to the reference node to thereby adjust the value of the reference voltage. A voltage sensing circuit develops the voltage control signal that is applied to the coupling circuit in response to the reference voltage.