Abstract: An oscillator circuit configured to generate an output signal having a frequency comprising a current source, a trim circuit, and one or more capacitors. The current source may be configured to generate a temperature independent current in response to a first adjustment signal. The trim circuit may be configured to generate the first adjustment signal. The one or more capacitors may be configured to charge to a controlled voltage using the temperature independent current. The controlled voltage may regulate a variation of the frequency of the output signal.

Abstract: A VCO includes a non-inverting output and an inverting output coupled to symmetrical circuitry configured to produce an oscillating output at the outputs. The symmetrical circuitry can include, for example, matched devices such as voltage-controlled resistors (VCRs) and capacitors. The symmetrical circuitry coupled to the non-inverting output and inverting output results in a stable output that operates close to the optimal 50% duty cycle independent of frequency and across a wide range of frequencies. In an alternative embodiment, the VCO further includes an output differential amplifier having its non-inverting input coupled to the non-inverting output and its inverting input coupled to the inverting output. The VCO according to this embodiment exhibits higher gain and a stable output that operates close to the optimal 50% duty cycle independent of frequency and across a wide range of frequencies.

Abstract: In the particular embodiments of the invention described in the specification, a first signal generator produces a signal which changes in cycles having approximately straight line segments between maximum and minimum values at a first rate and a second signal generator produces a signal which changes in cycles having approximately straight line segments at a second rate which is an order of magnitude greater than the first rate. The maximum level of the second signal during any cycle is dependent upon the instantaneous signal level of the first signal and the minimum level of the second signal during any cycle is dependent upon a selected fraction of the instantaneous signal level of the first signal. The second signal is used to control the speed of a motor in a continuously changing random manner.

Abstract: An adjustable voltage controlled oscillator has an input for receiving a voltage signal and an integrator coupled to the input for generating a ramp signal. The circuit also includes an adjustable current supply coupled to an output of the integrator for supplying an adjustable amount of current. A comparator compares the ramp signal with a predetermined voltage. The circuit further includes an output for generating a frequency output as a function of the comparison, wherein the circuit is calibratible by adjusting current generated by the adjustable current supply.

Abstract: The inverter functioning as a comparator, dummy inverter having the same electric characteristics as the inverter, and control circuit are provided. Vth detecting input voltage output from the control circuit is input into the dummy inverter, Vth detecting output voltage output from the dummy inverter is input into the control circuit, and the threshold voltage of the dummy inverter is detected. The threshold voltage of the inverter is controlled by controlling the back gate voltages of the MOS transistors of the dummy inverter and the inverter in such a manner that the threshold voltage of the dummy inverter coincide with an external reference voltage.

Abstract: A source-coupled oscillator contains two main MESFETs which supply current to respective loads and which have sources connected through a capacitor. Each of the main MESFETs is supplied with a constant current which can be adjusted to vary the frequency of the oscillator. The output signals are derived from the voltage across the loads. The oscillator also contains two differential pairs of MESFETs that change state as the main MESFETs are turned on and off and are connected so as to switch current into one or the other of the loads. Each of the differential pairs is supplied with a constant current. The currents supplied by the differential pairs act as compensating currents and are adjusted so that when the currents through the two main MESFETs are changed to vary the frequency of the oscillator, the total current through the loads remains constant.

Abstract: An oscillator has a slope-fixing circuit that generates a control signal and fixes the slope of the control signal, a swing-fixing circuit that fixes the swing of the control signal, and a switching block that generates an output signal having a frequency derived from the swing and the slope of the control signal. The slope-fixing circuit comprises a fixed timing capacitor C1 in parallel with a plurality of switchable timing capacitors C2 . . . CN to provide an effective capacitance C. The slope of the control signal is determined by the ratio of a control current I to the effective capacitance C. The swing-fixing circuit comprises a replica cell that accepts a programmable reference voltage VREF and provides a fixed voltage swing VSW=VDD−VREF across a pair of load transistors. The switching block comprises a pair of switching transistors that alternate between “on” and “off” states depending on the value of the control signal to produce an oscillating output signal.

Abstract: An integrated circuit (10) is disclosed comprising a fundamental frequency oscillator comprising a reference node (32) whose voltage varies between a high threshold and a low threshold. The fundamental frequency oscillator is operable to generate a first output at the fundamental frequency on a first output node (36). The integrated circuit (10) also comprises a circuit (C2) coupled to the reference node. The circuit (C2) is operable to sense the voltage at the reference node (32), to determine when the voltage exceeds an intermediate threshold between the high threshold and the low threshold, and to generate a second output in response to the determination. The integrated circuit (10) also comprises logic (40) coupled to the circuit (C2) and load circuitry (50) coupled to the logic (40). The logic (40) is operable to generate an output signal at an output frequency greater than the fundamental frequency in response to the second output and the first output.

Abstract: Presented is a low supply voltage oscillator circuit having at least one capacitor to be controlled, connected between first and second voltage references, and a circuit for charging and discharging the capacitor to be controlled. The oscillator circuit also includes at least first and second stages having symmetrical structures in a mirror-image configuration and being connected between the first voltage reference and the second voltage reference and connected together through a memory element. The oscillator circuit also includes respective primary switches for alternately charging the capacitors in a controlled fashion.

Abstract: Several calibration techniques for a precision relaxation oscillator with temperature compensation produces a stable clock frequency over wide variations of ambient temperature. The calibration techniques provide for different methods of determining CTAT current, PTAT current or the ratio of PTAT current to CTAT current. The calibration techniques provide different methods for determining CTAT and PTAT calibration values and for setting CTAT and PTAT calibration select switches.

Abstract: An apparatus and method for achieving accurate temperature-invariant sampling frequencies in a device, such as, a multiple message non-volatile multilevel analog signal recording and playback system is described. An oscillator is used to generate an oscillation frequency. A bandgap voltage generator generates a zero temperature coefficient voltage reference (V(OTC)) that is independent of temperature. This V(OTC) is applied to the oscillator. A variable temperature coefficient voltage (V(TC)) that compensates for temperature coefficient variations of a resistor to which V(TC) is applied produces a stable oscillator current Iosc. Therefore, the stable oscillator current Iosc is likewise independent of the temperature coefficient variations of the resistor. The stable oscillator current Iosc is applied to the oscillator such that the oscillator generates a stable temperature-invariant oscillation frequency.

Abstract: A timing device for keeping time by marking the time boundaries between contiguous time periods. Time is measured by measuring charging voltage on a pair of capacitances where each capacitance is charged and discharge in successive cycles. Detection of a preset value of potential on each one of the capacitances is used to initiate commencement of charge on the other capacitance and detection of another preset value on the other capacitor is used to record measurement of potential at a full scale potentail point on the one capacitor. By this means “dynamic” measurements of potential are made by which is meant that the potentials are measured while the potential is changing and rather than when the potential has reached a target end point. This technique eliminates errors arising from unstable conditions at the capacitor due to, for example, dielectric hysteresis, a requirement to measure a charging or discharging step simultaneous with a measuring step, etc.

Abstract: An oscillator circuit includes a current generator which supplies current to input terminals of capacitors in a trimmable capacitor array. The input terminals of the capacitors are held at a relatively constant voltage, and thus all of the current from the current generator passes through the desired capacitors of the capacitor array, thus minimizing the effect of parasitic capacitance.

Abstract: A frequency comparator includes a circuit comparing, independently of a phase relationship between first and second clocks, frequencies of the first and second clocks and outputting first and second detection signals when the first clock has frequencies higher and lower than those of the second clock, respectively. The first and second detection signals are output for respective times based on a difference between the frequencies of the first and second clocks.

Abstract: An oscillation circuit for outputting an oscillation signal includes a comparison circuit and a reference signal generation circuit. The comparison circuit compares two voltage levels and outputs a comparison result as the oscillation signal. The reference signal generation circuit provides a signal input to the comparison circuit. The reference signal generation circuit includes at least two resistance means coupled with each other in series, where one resistance means is given a smaller regulation of the resistance value relative to the temperature as compared with other resistance means.

Abstract: A current source and a load circuit. The oscillator circuit may be configured to present an output signal having a frequency in response to (i) a current, (ii) a load, and (iii) an input signal. The current source may be configured to generate the current in response to one or more first control signals. The load circuit may be configured to generate the load in response to one or more second control signals.

Abstract: A controller oscillator provides a periodic output signal having first and second output level states. The oscillator is responsive to an applied saw tooth signal that varies between first and second voltages (Vlow,Vhigh). The oscillator is comprised of a comparator (82) the non-inverting input of which receives the saw tooth signal applied thereto to produce the periodic output signal at its output (86). A first voltage reference circuit (88, 90, and 92) generates the second voltage (Vhigh) that is applied to the inverting input of the comparator while the periodic output signal is at the first output level state and the input signal charges from the first voltage (Vlow) towards the second voltage. As the input signal becomes equal to the second voltage the output of the comparator switches to the second output level state and a second voltage reference (92,94, 96) provides the first voltage at the inverting input of the comparator.

Abstract: An electronic delay circuit (10) useful for the delayed initiation of detonators illustrates several novel features that may be combined, including a novel oscillator (34), a programmable timer circuit (32) and a run control circuit (46). The oscillator (34) generates a clock signal determined by the rate of discharge of a capacitor (34a) relative to a reference voltage REF. A second capacitor (34b) is charged to a voltage that exceeds REF, and when the first capacitor (34a) falls below REF, an internal signal is generated and the capacitors are switched, so that the first capacitor gets charged while the second is discharged. A latch (34f) produces clock pulses in response to the internal signals. The programmable timer circuit (32) includes a ripple counter (38) and a program bank (40) that loads a count in the counter upon initialization.

Abstract: A spiking neuron circuit providing a spiking output signal in response to an input current that causes a first capacitor to charge to a threshold voltage. In response to achieving such threshold, an output terminal is connected to a voltage, illustratively VDD, for a period determined by an applied voltage, Vpw. Rapid switching of the output to its spiking level is achieved using a positive feedback path, and deactivation of such feedback rapidly terminates the spiking period.

Abstract: A voltage controlled oscillator has first and second complementary output terminals. A first edge delay circuit has an input terminal, an output terminal, and a control input terminal. The input terminal is coupled to the first complementary output terminal. A first comparator has a first, second and third input terminal, an output terminal, and a control input terminal. The first input terminal is coupled to the output terminal of the first edge delay circuit. The second input terminal is coupled to the first complementary output terminal. The first comparator output terminal is coupled to the second complementary output terminal. A second edge delay circuit has an input terminal, an output terminal, and a control input terminal. The input terminal is coupled to the second complementary output terminal. A second comparator has a first, second and third input terminal, an output terminal, and a control input terminal. The first input terminal is coupled to the output terminal of the second edge delay circuit.

Abstract: A circuit measures the signal propagation delay through a selected test circuit. The test circuit is provided with a feedback path so that the test circuit and feedback path together form a free-running oscillator. The oscillator then automatically provides its own test signal that includes alternating rising and falling signal transitions on the test-circuit input node. These signal transitions are counted over a predetermined time period to establish the period of the oscillator. The period of the oscillator is then related to the average signal propagation delay through the test circuit. The invention can be applied to synchronous components that might fail to oscillate by connecting the asynchronous set or clear terminal to the output terminal so that the oscillator oscillates at a frequency determined by the clock-to-out delay of those components.

Abstract: Disclosed are an integration circuit capable of substantially raising the ratio of a current to a capacitance, I/C, and voltage-controlled oscillator and frequency-voltage converter which employ the integration circuit. The integration circuit comprises an integrating capacitor, a current source, a switch, a detection circuit, and a control circuit. The current source supplies a current to the integrating capacitor. The switch is installed on a path along which a current is supplied from the current source to the integrating capacitor. The detection circuit detects a voltage developed at the integrating capacitor. The control circuit controls the switch so that a current will be supplied from the current source to the integrating capacitor during an integration period. The integration period falls into a current supply period and a stop period.

Abstract: A relaxation oscillator, such as a voltage controlled oscillator (VCO), with automatic swing control feedback which dynamically monitors the voltage swing across a capacitor and adjusts the oscillator threshold voltage, at which reversal of the polarity of the charging/discharging current occurs, to maintain the effective voltage swing at a constant level. The improved relaxation oscillator provides a very wide linear range of frequency variation versus control voltage (or current) and allows for the extendibility of linear operation to or near the maximum frequency that can be practically achieved by the oscillator circuitry.

Abstract: A circuit including an oscillator circuit, a current generator circuit and a voltage generator circuit. The oscillator circuit may be configured to generate an output signal having a frequency in response to (i) a first control signal and (ii) a second control signal. The current generator may be configured to generate said first control signal in response to a first adjustment signal. The voltage generator circuit may be configured to generate the second control signal in response to a second adjustment signal.

Abstract: An oscillator having compensation for the response delays of a Schmitt trigger has a first current source that provides a charging current to a capacitor and a second current source for providing a discharging current to the capacitor. The oscillator includes a Schmitt trigger circuit that receives a charge/discharge voltage from the capacitor and generates a square wave oscillator output signal therefrom. The oscillator further includes charge and discharge current control units that compare the charge/discharge voltage from the capacitor to respective charge and discharge threshold voltages. Based on the comparison, the control units divert the flow of charging and discharging current from the capacitor during the response delays of the Schmitt trigger circuit.

Abstract: A method for generating a positive temperature correlated clock frequency is described. The method comprises conducting current through a resistor to charge a capacitor. When the capacitor is charged to a trip point of the inverter at the input of the inverter chain, a transition in an output signal of an inverter chain is triggered. The capacitor is discharged through a grounding device when the output signal activates said grounding device.

Abstract: An oscillator circuit generates an output frequency that is substantially independent of power supply and temperature variations. The oscillator circuit can be implemented using conventional complementary metal-oxide-semiconductor technology. The oscillator circuit is suitable for use as an internal oscillator for generating a stable reference frequency in telecommunication receiver modules.

Abstract: An oscillator circuit produces first and second oscillating logic signals that are of a same frequency and are non-overlapping in a first logic state. This oscillator includes a flip-flop circuit to produce third and fourth oscillating logic signals of opposite polarities, this flip-flop circuit being driven by first and second driving logic signals. First and second logic gates receive the third and fourth logic signals and produce the first and second logic signals, the logic state transitions in the first and second logic signals being produced as a function of the logic state transitions of the third and fourth logic signals. The first and second logic gates are organized so as to introduce a delay into the transitions from a second logic state to the first logic state, in the first and second logic signals, with respect to transitions in the third and fourth logic signals.

Abstract: A method for calibrating a frequency device by monitoring its output cycles over a first plurality of monitoring windows is disclosed. An accumulation of these monitored cycles is used to determine a correction for the device over a second plurality of monitoring windows. A method for obtaining fractional correction values to be applied for controlling the frequency device is also disclosed.

Abstract: Relaxation oscillator comprising a chain of coupled sawtooth generator stages. Each stage has a capacitor which is charged and discharged. The charging of a capacitor begins when the voltage (C.sub.C1) of a previous stage reaches a threshold voltage (V.sub.H). To avoid sampling of noise on the threshold voltage (V.sub.H) each new voltage ramp is started gradually.

Abstract: A current-controlled oscillator includes a capacitor, and at least one current source for providing at least one charge current for charging the capacitor. A discharge circuit sequentially discharges the capacitor with a discharge current. A control circuit maintains a mean charge voltage of the capacitor at a preset value by controlling the discharge current. The control circuit includes a current control source forming a current mirror with the at least one current source. The current control source is connected to the discharge circuit for setting the discharge current substantially equal to a sum of the charge currents. The oscillator further includes a correction circuit for correcting the discharge current corresponding to a mean charge of the capacitor.

Abstract: An oscillation device includes a buffer device, a feedback device for feeding back an output of the buffer device to an input thereof and a charging device and a discharging device connected to the input of the buffer device. The charging device includes a first switching device that is turned on and off based on the output of the buffer device and a first current control device that controls the current flowing into the input of the buffer device through the first switching device. The discharging device includes a second switching device that is turned on or off based on the output of the buffer device and a second current control device that controls the current flowing out of the input of the buffer device through the second switching device. The first and second switching devices include first and second transistors and the first and second current sources that include third and fourth transistors.

Abstract: A voltage compensated oscillator circuit having a resistor capacitor (RC) circuit for setting a frequency of oscillation for the oscillator circuit. A switching circuit with hysterisis is coupled to the RC circuit for providing upper and lower threshold limits. The upper and lower threshold limits being used for controlling the direction of switching of the oscillator circuit. By adjusting the upper and lower threshold limits, one may compensate for voltage signal fluctuations so that the frequency of oscillation will not change due to power supply voltage fluctuations.

Abstract: An oscillator with temperature compensation produces a stable clock frequency over wide variations of ambient temperature, and it includes an oscillation generator, two independent current generators, a transition detector and a clock inhibitor. The outputs of the two programmable, independent current generators are combined to provide a capacitor charging current that is independent of temperature. The oscillator is capable of three modes of operation: fast mode, slow/low power mode and sleep mode, which are controlled by the transition detector in response to external control signals. When the transition detector transitions from one mode to another, it controls the clock inhibitor to block a clock output of the oscillator generator for a predetermined number of clock cycles to allow the clock output to stabilize. The oscillator is implemented on a single, monolithic integrated circuit.

Abstract: A controllable reactance implemented within an integrated circuit includes a first sub-circuit (20) comprising a reactive element, for example a capacitor 12, coupled in series with a transistor (14). A controllable current source (16) injects a controllable bias current through the transistor (14) to vary the effective resistance of the transistor (14) and hence the effective complex impedance of the capacitor combination. A second transistor (18) amplifies the current to increase the effective capacitance. Preferably, a second sub-circuit (24) includes corresponding components (26, 28, 30) to mirror the real component of the current flowing in the first sub-circuit (20), and transistors (32 and 34) to reflect an inverse current to the coupling node line (22) to cancel the real component of the current at the node, to thus simulate a purely capacitive circuit. An oscillator embodying this circuit is also disclosed.

Abstract: A voltage-controlled oscillator VCO capable of reliably generating an oscillation even if it, after stopping with electric charges remaining on both of its capacitors, is restarted under the same conditions. Even if the VCO is started with charges remaining on capacitors, N-channel transistors are both turned on because outputs of differential circuits are both at H level. N-channel transistors are both turned off because their gates are connected with the drains of the N-channel transistors. Therefore, in no case, the levels at points C and D as outputs on both sides of latch circuit go to L level at the same time.

Abstract: A precision relaxation oscillator with temperature compensation produces a stable clock frequency over wide variations of ambient temperature. The invention has a oscillation generator and two independent current generators. The outputs of the two programmable, independent current generators are combined to provide a capacitor charging current which is independent of temperature. The precision relaxation oscillator with temperature compensation is implemented on a single, monolithic integrated circuit.

Abstract: In a method of calibration of a voltage controlled oscillator (VCO), the VCO (100) provides an output signal which is used to drive a dividing oscillator (10) such as a relaxation oscillator (RO). The RO has at least two states, one in which the RO provides an output signal which has a first frequency that is related to the VCO output signal by a first ratio (e.g. 1/N) and one in which the relaxation oscillator provides a RO output signal which has a second frequency that is related to the VCO output signal by a second ratio (e.g. 1/(N+1)). By measuring the first and second frequencies (and knowing the relationship between the first and second ratios), the VCO frequency is calculated and stored (110). Several VCO frequencies can be calculated and stored for several applied voltages. As a result the VCO can be driven to any selected frequency in the calibrated range and can be used to provide an injection frequency for a radio.

Abstract: An integrated RC oscillator circuit includes a reference voltage generator, a fine tuner, a charging/discharging oscillator, a frequency counter, and a comparator. The reference voltage generator generates stable reference voltages Vref, Vref 1 to Vref 31, 3/4Vref and 1/2Vref. The fine tuner receives as inputs a reset signal, Vref and Vref 1 to Vref 31 and outputs a reference voltage PVref (0<P<1). The charging/discharging oscillator receives as inputs an enable signal, PVref, Vref, 3/4Vref and 1/2Vref and outputs a square wave signal whose frequency is determined by a resistor, a capacitor and the value of P. The frequency counter receives as inputs the reset signal, a timing reference clock and the square wave signal, it counts the frequency of the square wave signal and outputs the frequency value, and it also outputs a PROGRAM signal to the fine tuner.

Abstract: A clock generator or oscillator circuit for use in an integrated circuit for generating a clock signal includes a 555 timer circuit. The time constant circuit of the 555 timer includes a heater element for generating heat and a transducer for converting heat generated by the heater element into electrical energy. The clock signal is generated in response to the heating and cooling of the heater element.

Abstract: A precision oscillator includes a capacitor, a charging current source, a discharging current source, a switch for alternatingly connecting the capacitor to the charging current source and the discharging current source, and a hysteretic comparator connected to the capacitor for producing an oscillating signal responsive to charging and discharging the capacitor. The oscillator may also preferably include a duty cycle controller connected to at least one of the charging current source and the discharging current source for setting the charging current and/or the discharging current to thereby set a duty cycle of the oscillating signal by setting a ratio of the charging and discharging currents. The charging current source may have a current setting input for permitting setting of a charging current to the capacitor, and the discharging current source may have a current setting input for permitting setting of a discharging current from the capacitor.

Abstract: There is provided a CR oscillating circuit from which oscillation frequency is obtained as targeted, when MOS capacitors having large voltage dependency are used therein. The circuit is constructed such that bias voltage is applied always to the two MOS capacitors by connecting the two MOS, capacitors in series in the opposite direction from each other and by connecting further a MOSFET.

Abstract: A magnetic sensor includes a DC power source, a multivibrator circuit composed of two CMOS inverters, a resistor, and a capacitor, each of the CMOS inverters being composed of a pMOS transistor and an nMOS transistor connected in series, and a magneto-impedance element. In a transition state attributable to switching operations of the CMOS inverters, a sharp pulse current is caused to flow through the magneto-impedance element so as to excite the magneto-impedance element sufficiently causing the skin effect, whereas in a steady state, the flow of the current is stopped by the CMOS inverters so as to reduce power consumption.

Abstract: A temperature sensitive oscillator circuit and control circuit which together form a current source. The temperature sensitive oscillator circuit generates an output signal which controls a frequency of a refresh oscillator circuit. The duty cycle of the output signal of the temperature sensitive oscillator circuit is temperature dependent and increases for increases in temperature. The output signal of the temperature sensitive oscillator circuit controls the control circuit which sources current between the refresh oscillator circuit and a supply node. As the duty cycle of the output signal of the temperature sensitive oscillator circuit increases a time duration during which the control circuit sources current between the refresh oscillator circuit and the supply node increases. This increase increases the frequency of the output signal of the refresh oscillator circuit. The output signal of the refresh oscillator circuit is an internal clock signal which controls a refresh cycle of a memory circuit.

Abstract: An oscillator circuit is described which produces a periodic oscillator output signal. The frequency of the oscillator output signal is essentially independent of the supply voltage provided to the oscillator circuit. The oscillator circuit includes a capacitor which is periodically charged and discharged. A high trip point inverter and a low trip point inverter detect the voltage level of the capacitor and set and reset, respectively, a flip-flop. The flip-flop produces an output signal which controls the charge and discharge of the capacitor through charging and discharging circuit paths, respectively. The impedance presented by the charging and discharging circuit paths varies as a function of the supply voltage, such that the high and low trip point inverters are switched at a frequency which is essentially independent of the supply voltage magnitude. The oscillator output signal is derived from the flip-flop output signal.

Abstract: A precision oscillator circuit having a wide adjustable operating frequency range and an adjustable duty cycle. The precision oscillator use a window comparator circuit for monitoring a voltage of a capacitive element. The window comparator circuit has a first operating voltage edge and a second operating voltage edge wherein the first operating voltage edge latches an output signal of the window comparator circuit at one level when the voltage of the capacitive element is greater than the first operating voltage edge. The second operating voltage edge brings the output signal of the window comparator circuit back to an initial level when the voltage of the capacitive element is greater than the second operating voltage edge. A precision current reference source is coupled to the capacitive element and to the window comparator circuit. The precision current reference is used for generating currents which are insensitive to temperature, supply voltage, and process variations.

Abstract: A first capacitor is charged by a driving current. A second capacitor is charged by a driving current. A first discharging transistor discharges the first capacitor in accordance with a charged voltage of the second capacitor. A second discharging transistor discharges the second capacitor in accordance with a charged voltage of the first capacitor. The oscillation circuit generates an oscillation signal in accordance with the charged voltages of the first and second capacitors. An oscillation restarting circuit, when the first and second discharging transistors simultaneously perform discharging and thus oscillation stops, causes the discharging of the second discharging transistor to stop, and thereby, restarts the oscillation.

Abstract: A system and method for ensuring a substantially constant oscillator frequency that is substantially independent of the operating temperature and is substantially independent of variations of the supply voltage level where the oscillator is an on-chip oscillator without requiring significantly additional logic, e.g., not requiring the use of multiple comparators and enabling post packaging modifications of the oscillator frequency. The present invention utilizes one or more paired resistors as part of the RC oscillator where each of the one or more pairs are matched according to their temperature coefficient. That is, each pair includes a resistor with a positive temperature coefficient and a resistor with a corresponding negative temperature coefficient. In addition, the present invention enables post packaging modifications to the resistors based upon one or more program signals that can modify the resistance by forming a short circuit around one or more resistor pairs.

Abstract: An improved oscillator circuit 400 having a frequency that is substantially independent of temperature. The improved oscillator circuit is particularly well suited for use in an integrated circuit device to produce a clock signal, such as a refresh clock for a dynamic random access memory (DRAM) integrated circuit. The current i.sub.c produced is temperature independent so that the refresh frequency for the DRAM integrated circuit is stable over temperature.

Abstract: An oscillation circuit for producing an output whose frequency accords with an input voltage value, comprises a first constant current source whose current has a value according to the input voltage value; a charge capacitor to be charged by the first constant current source; a comparator having one input terminal connected to a charge terminal of the charge capacitor to be charged and an other input terminal supplied with a first reference voltage, for comparing inputs to both input terminals with each other and outputting an output signal having a high level or a low level; and first switch means for pulling down a potential of the charge terminal of the charge capacitor to a second reference voltage lower than the first reference voltage under control by an output of the comparator.