Abstract: A differently-tuned voltage controlled oscillator (VCO) and its application in a multi-band VCO tuner are disclosed. In one aspect of the invention, the VCO comprises a plurality of serially connected inductive elements each including inductively coupled inductor elements, a varactor element connected in parallel with the serially connected first inductor elements and means to apply a first and second tuning voltage to elements of the varactor element. In a second aspect, the VCO further comprises a second varactor element connected in parallel with the inductive elements, and means to apply the second tuning voltage elements of the second varactor element.

Abstract: A differential negative resistance source that provides negative resistance to a differential resonator of a differential VCO. The differential negative resistance source includes first and second active devices, each having first and second current terminals and a control terminal, first and second current sinks, each coupled to a corresponding one of the second current terminals of the first and second active devices, and at least one capacitive device coupled between the second terminals of the first and second active devices. The capacitive device and the separate current sinks form a capacitive degeneration circuit that operates to reduce or otherwise eliminate net differential capacitance at the output of the differential negative resistance source. The capacitive degeneration offsets extra capacitance, which enables an increase of the maximum operating frequency for a given process, and which enables the VCO to be less sensitive to operating conditions.

Abstract: An object of the present invention is to provide an oscillator contributing to a reduction of power dissipation. An oscillator 10 comprises four inductors 11—1, 11—3, 11—2, and 11—4 connected in series to constitute a closed circuit, and four capacitors 12—1, 12—3, 12—2, and 12—4 one ends of which are connected to nodes that are connecting points of the inductors, and another ends of which are held at a power supply VDD. The oscillator 10 is formed on a semiconductor substrate.

Abstract: A voltage controlled oscillator includes two gain stages to split the bias current and reduce phase noise.

Abstract: In a wideband variable frequency voltage controlled oscillator, an LC resonance circuit determines an oscillation frequency based on an externally inputted voltage signal. A negative resistance generating circuit generates a signal having the oscillation frequency determined by the LC resonance circuit. A buffer circuit transfers the oscillation frequency generated by the negative resistance generating circuit to a load. A variable capacitor connecting circuit connects the negative resistance generating circuit and the buffer circuit to transfer the signal having the oscillation frequency from the negative resistance generating circuit to the buffer circuit.

Abstract: The present invention generally relates to voltage-controlled oscillators. More specifically, the present invention relates to method and circuitry for implementing a differentially tuned varactor-inductor oscillator. In one exemplary embodiment, the present invention includes an LC tank circuit having a couple of terminals, a first and second capacitors, and a first and second varactors. The first and second varactors are connected in series forming a first and a second node. The first capacitor connects the first node and one terminal of the LC tank circuit. The second capacitor connects the second node and the other terminal of the LC tank circuit. A pair of differential input control signals is applied across the first and the second varactors, respectively, to tune the LC tank circuit thereby generating an oscillator output.

Abstract: A phase detector (PD) generates an up/down signal based on the phase error between data and clock signals input to the phase detector. A voltage controlled oscillator (VCO) generates the clock signal. The up/down signal is applied to a proportional charge pump and a truncated version of the up/down signal is applied to an integral charge pump. The proportional charge pump generates a first voltage for a first time period across a resistor based on the up/down signal, while the integral charge pump generates a second voltage for a second time period across a capacitor based upon the truncated version of the up/down signal and the sampling rate of the data signal by the PD. The second time period is less than the first time period. The first and second voltages are combined and applied to the VCO to drive the clock signal to synchronization with the data.

Abstract: An oscillator includes a resonance circuit, and a feedback circuit coupled to the resonance circuit. The resonance circuit includes a main resonance element circuit, and a voltage dividing circuit that divides an output voltage of the main resonance element circuit and applies a divided voltage to the feedback circuit.

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: A voltage-controlled oscillator (VCO) having a bandpass filter includes an oscillation circuit and a bandpass filter. The oscillation circuit outputs a first oscillation frequency with a harmonic distortion according to a tuning voltage. The first oscillation frequency is then input to the bandpass filter and the harmonic distortion of the first oscillation frequency is filtered. Therefore, a second oscillation frequency without the harmonic distortion is output from the bandpass filter. The invention is characterized by that the bandpass filter that removes the harmonic distortion from the VCO.

Abstract: An anchor to hold getter materials in place within a micromechanical device package substrate. First and second cavity faces define an anchor cavity and mechanically retain a getter away from a region holding the micromechanical device. The getter anchor may be formed in a substrate comprised of at least three layers. The layers form a cavity in the substrate with a wide bottom portion—formed in the middle layer and a relatively narrower top portion—formed by the top layer. The narrow portion helps to retain the getter in the cavity by creating a mechanical lock on the wide portion of getter in the bottom of the cavity.

Abstract: A cross-coupled differential MOS oscillator having reduced phase noise is applicable to a RF communication device such as a transmitter or receiver. The oscillator having low phase noise is formed of a frequency dependent amplifier to amplify a signal having a fundamental frequency; a frequency dependent feedback device that is connected between an output of the frequency dependent amplifier and an input of the frequency dependent amplifier to feed a portion of an amplified signal having the fundamental frequency to an input of the frequency dependent amplifier to stimulate oscillation; and a attenuating device in communication with the frequency dependent amplifier. The attenuating device reduces the gain of the frequency dependent amplifier for signals having frequencies much, much less than the fundamental frequency to decrease the phase noise.

Abstract: In a particular embodiment, an oscillator adjustment circuit is disclosed. The oscillator adjustment circuit includes a resonator portion comprising a capacitive element coupled to an inductive element and a signal balancing portion comprising a secondary coil of the transformer. The inductive element comprises a primary coil of a transformer. The secondary coil has a grounded center tap.

Abstract: MEMS-based, computer system, clock generation and oscillator circuits and LC-tank apparatus for use therein are provided and which are fabricated using a CMOS-compatible process. A micromachined inductor (L) and a pair of varactors (C) are developed in metal layers on a silicon substrate to realize the high quality factor LC-tank apparatus. This micromachined LC-tank apparatus is incorporated with CMOS transistor circuitry in order to realize a digital, tunable, low phase jitter, and low power clock, or time base, for synchronous integrated circuits. The synthesized clock signal can be divided down with digital circuitry from several GHz to tens of MHz—a systemic approach that substantially improves stability as compared to the state of the art. Advanced circuit design techniques have been utilized to minimize power consumption and mitigate transistor flicker noise upconversion, thus enhancing clock stability.

Abstract: A cascaded voltage controlled oscillator is described that includes a first oscillator stage having a first oscillator stage first input, a first oscillator stage second input and a first oscillator stage output. A second oscillator stage includes a second oscillator stage input and a second oscillator stage output wherein the first oscillator stage output is input to the second oscillator stage input and wherein the second oscillator stage output is fed back to the first oscillator stage second input. A third oscillator stage includes a third oscillator stage input and a third oscillator stage output wherein the second oscillator stage output is fed to the third oscillator stage input.

Abstract: At the same control voltage Vtune, the oscillation frequency with only switches SW3 and SW4 being closed is higher than that with only switches SW1 and SW2 being closed. Accordingly, even when the oscillation frequency is lower than designed with only the switches SW1 and SW2 being closed and the capacitance of varactor diodes D1 and D2 cannot be controlled to provide the desired oscillation frequency, the desired oscillation frequency can be provided by closing only the switches SW3 and SW4 to control the capacitance of the varactor diodes D1 and D2. On the oscillation frequency, a coarse tuning can be performed by controlling the switches SW1 to SW4, while a fine tuning can be performed with the varactor diodes D1 and D2. Consequently, the range of the oscillation frequency is increased.

Abstract: A structure and associated method for controlling an amplitude of oscillation in a voltage controlled oscillator. The voltage controlled oscillator circuit comprises a drive circuit, an inductor/capacitor (LC) tank circuit, and a diode. The LC tank circuit and the drive circuit collectively comprise a first oscillating node and a second oscillating node. The first oscillating node is adapted to have a first voltage. The second oscillating node is adapted to have a second voltage. The first diode is adapted to control an amplitude of the first voltage and an amplitude of the second voltage.

Abstract: A phase synchronous multiple LC tank oscillator includes a plurality of oscillator stages configured to oscillate synchronously. The phase of each of the plurality of oscillator stages is substantially the same.

Abstract: The invention proposes a device for providing tunable high-frequency and/or radio-frequency comprising within one IC-package at least four signal paths providing at least two input and at least two output ports (rf-port1, rf-port2, rf-prot3, rf-port4) at least one active component (T) and at least one variable passive component (C1, C2) connected at least with an input port of the active component (T), and at least one control path for controllable tuning the at least one variable passive component (C1, C2).

Abstract: A voltage-controlled oscillator including an active oscillator circuit, an inductor, and capacitive circuits is disclosed. The capacitive circuits are selectively turned on and off to control the frequency of the voltage-controlled oscillator. Particularly, the inductor and the capacitors in the capacitive circuits form LC circuits that provide feedback to the active oscillator circuit. To avoid damage to the switches in the capacitive circuits, the capacitive circuits further comprise resistors. The resistors can be configured in several different ways so that the voltage-controlled oscillator can have a high degree of reliability, and a wide tuning range with constant phase noise performance.

Abstract: There are provided an internal oscillation transistor; a terminal that is connected to the base of the oscillation transistor and to which an external resonance circuit is to be connected; and two internal diodes provided between the terminal and the ground, for preventing electrostatic breakdown of the oscillation transistor. The cathodes of the two diodes are connected to each other and supplied with a reverse-bias voltage. The anode of one diode is grounded and the anode of the other diode is connected to the terminal by a first resistor. An internal second resistor for DC-grounding the terminal is also provided.

Abstract: According to some embodiments, unilateral coupling is provided for a quadrature voltage controlled oscillator. For example, a first voltage controlled oscillator may be provided with a 0 degree phase node and a 180 degree phase node A second voltage controlled oscillator may be provided with a 90 degree phase node and a 270 degree phase node. In addition, the first and second voltage controlled oscillators may be mutually coupled with substantially unilateral cascaded common-source common-gate amplifier coupling devices to create a quadrature voltage controlled oscillator.

Abstract: A voltage-controlled oscillator device with an LC-resonant circuit, in particular for implementing integrated voltage-controlled oscillators for the lower GHz range, is disclosed. The device achieves continuous frequency tunability in a wide range in particular with a low level of phase noise and phase jitter. In the voltage-controlled oscillator, a second inductor can be periodically switched in parallel and/or in series with at least one first inductor of the LC-resonant circuit by way of a switching means actuated with the oscillator frequency. A control input of the switching means is connected to a variable dc voltage. In that respect the relationship of the duration of the conducting state and the duration of the non-conducting state of the switching means is variable within an oscillation period of the oscillator in dependence on the value of the control voltage.

Abstract: A phase-locked loop (PLL) has an analog divider in the feedback path that receives either the in-phase or quadrature-phase pair of outputs from a voltage-controlled oscillator (VCO) while the other pair, 90-degree out-of-phase, of outputs from the VCO is used for the PLL output. Phases between the PLL's input and output are inherently aligned. The analog output of the analog divider is converted to a digital clock signal and applied to a cascade of digital dividers to generate a reduced feedback clock. The reduced feedback clock is applied to the D input and the digital clock signal is applied to the clock input of a pseudo D-flip-flop that drives the feedback input of a phase-frequency detector that drives the charge pump to the VCO input. Another cascade of digital dividers and pseudo D-flip-flop re-align the reference clock input to the phase-frequency detector. Analog and digital re-alignment circuits reduce internal skew.

Abstract: A voltage-controlled oscillator circuit compensates for supply voltage fluctuations of the oscillator and thus for frequency fluctuations at the oscillator output. An additional voltage-controlled capacitor is connected in parallel with the voltage-controlled capacitor of the LC resonant circuit. The control terminal of the second voltage-controlled capacitor is coupled to the supply voltage terminal, which feeds the oscillator circuit. The oscillator circuit can be monolithically integrated and can be employed in phase-locked loops, for example.

Abstract: An inductor element 30 effectively functions even when formed on a substrate and comprises two upper and lower conductors 1, 2 spirally formed on the front side of a semiconductor substrate 3. The conductors 1, 2 have substantially the same shape. When viewed from the above of the front side of the substrate 3, the two conductors 1, 2 are superposed one on the other almost exactly. Lead wires 6a, 6b are connected to the outer end (outer peripheral end) and the inner end (center end) of the conductor 1, respectively. The outer end of the conductor 1 is connected to the inner end of the conductor 2 through a connection wire 6c. The conductor 1 functions as an inductor conductor and is connected to a circuit provided on the semiconductor substrate 3 through the lead wires 6a, 6b.

Abstract: A voltage-controlled oscillator in which a tunable resonator (102) having a first port (132) and a second port (106) is disclosed. In one embodiment, the tunable resonator is a series resonating circuit having low driving and load impedances. A power gain element (108) is coupled to the first port and the second port, and an output port (110) is coupled to the power gain element and the second port. The first impedance at the first and second ports is less than approximately ten ohms. The voltage-controlled oscillator is capable of generating a signal at the output port of greater than approximately half a watt.

Abstract: A load-pulled oscillator circuit in which RF blocking on the power supply connections is achieved by an active stage rather than an inductor. This avoids the problems of temperature dependence, low-frequency oscillation, and backward tuning which can occur when using an inductor in a load-pulled oscillator.

Abstract: An oscillating circuit is constructed by a capacitor in an integrated circuit and an external conductive wire. The external conductive wire is used as an inductor and the inductance thereof is determined by a diameter and a length of the conductive wire. In addition, a conductive film is connected to the conductive wire and ground. Output frequency of the oscillating circuit can be tuned by cutting the conductive film to adjust the capacitance and the inductance of the oscillating circuit.

Abstract: In an embodiment consistent with the present invention, a semiconductor device having a oscillating circuit comprises: a first transistor having a control electrode and having one end and the other end of a current path thereof; a second transistor having a control electrode and having one end and the other end of a current path thereof, the control electrode is coupled to one end of the current path of the first transistor and one end of the current path thereof is coupled to the control electrode of the first transistor; a current mirror circuit that supplies a current to one end of the current path of the first transistor and one end of the current path of the second transistor; an inductor coupled to one end of the current path of the first transistor and one end of the current path of the second transistor; a first capacitor coupled to one end of the current path of the first transistor and one end of the current path of the second transistor; and a second capacitor and a switch element coupled with, are

Abstract: The present invention generally relates to voltage-controlled oscillators. More specifically, the present invention relates to method and circuitry for implementing a differentially tuned varactor-inductor oscillator. In one exemplary embodiment, the present invention includes an LC tank circuit having a couple of terminals, a first and second capacitors, and a first and second varactors. The first and second varactors are connected in series forming a first and a second node. The first capacitor connects the first node and one terminal of the LC tank circuit. The second capacitor connects the second node and the other terminal of the LC tank circuit. A pair of differential input control signals is applied across the first and the second varactors, respectively, to tune the LC tank circuit thereby generating an oscillator output.

Abstract: An oscillator circuit includes an oscillator core having two capacitances, two inductors designed as bonding wires, and a de-attenuation amplifier coupled to the oscillator core. The inductors of the oscillator core, which is preferably embodied to be tunable, are connected to a leadframe by a respective terminal. A chip including the oscillator core and the deattentuation amplifier is configured on the leadframe. A resonance transformation circuit is preferably provided for coupling the oscillator core and the de-attenuation amplifier. The oscillator can be used in a mobile radio when there are high requirements with regard to the phase noise.

Abstract: A LC controllable oscillator (LCCO) according to the invention comprises a voltage-controlled oscillator (VCO) and a first voltage controlled current source (VCCS) of a first type for supplying a current to the VCO. The VCO is realized with a flit pair of VCCCS of the first type coupled with a second paw of VCCS of a second type end a LC resonator. The VCO generates a periodical oscillation frequency that is controllable by a control signal (V). The LCCO further comprises a replica scaled bias module (RSBM) supplied from the external voltage source. The RSBM is conceived to generate a control signal (BIAS CONTROL) for controlling the supplied current delivered by the first VCCS to the VCO.

Abstract: Techniques are provided for compensating for variations in capacitance of capacitors used in resonant circuits, particularly varactors used in voltage-controlled oscillators. Indications of actual varactor capacitances are used to determine which of several inductances to use in the resonant circuit with the varactor. The inductances may be composed of a bondwire inductance, and may also be composed of one or more coil inductors. Based on the determined capacitance indication, a bondwire is connected from a common bondpad to a selected bondpad to complete the resonant tank circuit such that an LC product of the tank circuit is within a desired or acceptable LC product range.

Abstract: A VCO circuit for a fractional-n PLL circuit is described for implementing a direct modulation scheme. An embodiment of the invention provides a bank of switchable capacitors used to stringently control the gain of the VCO (KVCO). The capacitors provide the stringent control necessary for direct modulation. The bank of switchable capacitors is used to coarsely tune the VCO circuit. A linear capacitor is placed in series with, the varactor to linearize the frequency/capacitance response of the varactor. The capacitor also serves to isolate a reference voltage that is used to bias the varactor diode to ensure the linear range of the varactor is within the voltage range of the VCO circuit power supply. The varactor is used for fine tuning of the VCO circuit. For one embodiment the input voltages to the VCO are across a resistance value sufficient to dampen noise picked up through an external loop filter.

Abstract: An apparatus having a radio frequency resonator, which has a coil, a capacitor means and at least one switch means being associated with another capacitor means, a resistor means and a high voltage supply means, one end of the switch means being connected to a junction of the coil and the capacitor means where a radio frequency voltage is provided, another end of the switch means being connected to ground with said another capacitor means and to the high voltage power supply means with the resistor means.

Abstract: A multi-band, voltage-controlled oscillator has a switching device that can be certainly be turned on and off. The oscillator includes a negative source generator coupled to an output of a buffer transistor from which an oscillation frequency of an oscillating transistor is released, a switching device for selectively switching between an output of the negative source generator and a positive power source, and a mode switching device receiving an output frequency switching signal from the outside. An output of the switching device controls an opening and short-circuiting operation of first switching device to selectively release oscillation outputs in a low frequency band and a high frequency band from an output port.

Abstract: A feedback system such as a phase locked loop (PLL) includes a second feedback loop which responds when a VCO control voltage is near either end of its range, by slowly adjusting additional tuning elements which control the VCO frequency. The second feedback loop is arranged to cause a slow enough change in the VCO frequency that the first traditional feedback loop adjusts the control voltage quickly enough in a direction toward its mid-range value to keep the VCO frequency substantially unchanged. The second feedback loop advantageously incorporates one or more digital control signals which preferably change no more than one bit at a time and with a controlled slow ramp rate. As a result, the PLL maintains phase accuracy so that the operation of the PLL, including subtle specifications such as input data jitter tolerance or output jitter generation when used for clock and data recovery applications, is not negatively impacted.

Abstract: A cross-coupled differential MOS oscillator having reduced phase noise is applicable to a RF communication device such as a transmitter or receiver. The oscillator having low phase noise is formed of a frequency dependent amplifier to amplify a signal having a fundamental frequency; a frequency dependent feedback device that is connected between an output of the frequency dependent amplifier and an input of the frequency dependent amplifier to feed a portion of an amplified signal having the fundamental frequency to an input of the frequency dependent amplifier to stimulate oscillation; and a attenuating device in communication with the frequency dependent amplifier. The attenuating device reduces the gain of the frequency dependent amplifier for signals having frequencies much, much less than the fundamental frequency to decrease the phase noise.

Abstract: A clock signal generating circuit includes an oscillator portion that sustains a ramped oscillating clock signal in a memory storage device electrically connected to the oscillator portion, a switch portion that supplements electrical energy to the oscillator portion, and a cycle controller connected to the oscillator portion and the switch portion to supplement energy to the oscillator portion when a peak voltage or current level of the clock signal falls below a predetermined value.

Abstract: A cascaded voltage controlled oscillator is described that includes a first oscillator stage having a first oscillator stage first input, a first oscillator stage second input and a first oscillator stage output. A second oscillator stage includes a second oscillator stage input and a second oscillator stage output wherein the first oscillator stage output is input to the second oscillator stage input and wherein the second oscillator stage output is fed back to the first oscillator stage second input. A third oscillator stage includes a third oscillator stage input and a third oscillator stage output wherein the second oscillator stage output is fed to the third oscillator stage input.

Abstract: An apparatus and method for continuous variable reactive impedance control. The apparatus and method enable the continuous variation of the reactive impedance of an oscillating circuit. A reactive component, in one embodiment a capacitor, is switched into the oscillating circuit for a duration at the beginning and end of each half cycle of the oscillation frequency. Through varying the duration, the oscillation frequency is varied between the frequency that occurs without the reactive component in the circuit and the frequency with the reactive component permanently in the circuit. A controller determines the duration and controls a switch coupled to the reactive component. The apparatus and method may be used to adjust the oscillation frequency of a resonant circuit or to match the resonant frequency to a driving frequency in a driven oscillating circuit so as to improve efficiency.

Abstract: A symmetrical oscillator includes a reactive element, such as an inductor, coupled between first and second active components, where the reactive element defines a fundamental resonant frequency with one or more capacitances of the oscillator. A first feedback circuit is coupled between the first active component and a common node, while a second feedback circuit is coupled between the second active component and the common node such that an output signal at substantially twice the fundamental resonant frequency is obtained at the common node.

Abstract: A cross-coupled cascode voltage controlled oscillator including a variable-frequency tank circuit, first and second cascode-coupled active devices coupled to the tank circuit, and third and fourth cascode-coupled active devices coupled to the tank circuit, the first and second active devices being cross-coupled to the third and fourth active devices. The invention produces lower drain the gate voltages resulting in fewer device failures.

Abstract: A VCO having an automatic amplitude control circuit In the form of a sensing amplifier provided in the feedback loop to sense the oscillator amplitude and draw current away only when the positive peak voltage Is above a certain value. In general, any amplifier may be used in the feedback loop that outputs current proportional to a peak positive input (in a non-linear and asymmetric fashion with respect to the changing voltage). In one example, the amplifier in the feedback loop comprises first and second transistors that are set nominally in cut off and behave as class C amplifiers. The advantage of this amplifier transistor configuration is that the amplifier they form has a low load on the LC tank circuit and a high input impedance.

Abstract: A method and apparatus for producing high-frequency oscillations is disclosed. A new resonator architecture minimizes via losses and supports a compact layout of active circuitry. The resonator architecture incorporates dual resonant transmission lines to reduce resonator loss and facilitate compact layout. The oscillations of two oscillators are cross-coupled in a way that compensates for the delay in the active devices of the oscillator, thus permitting accurate alignment of the active circuitry response with the oscillation waveform. The cross-coupling of the two oscillators improves phase noise performance and eliminates spurious oscillations. An active circuit architecture provides very narrow pulses for the operation of the oscillator. This architecture provides for accurate cross-coupling and pulsed-mode operation to improve manufacturing stability and phase noise performance.

Abstract: A circuit and method are disclosed herein for a multi-phase voltage-controlled LC oscillator. The oscillator is configured as a ring containing N sections, each of which has an LC tank circuit that determiines the oscillation frequency. All the oscillator sections produce a signal at the same frequency, but with a constant phase angle offset between one section and the next. Thus, for example, a 4-phase version of the oscillator would have 4 sections, producing signals with phase angles of 0°, 90°, 180°, and 270°. The phase offset in each section results from the use of amplified quadrature signals to drive the LC circuits. An advantage of this approach to obtaining multiple phases is enhanced frequency stability, since the LC circuits in the oscillator sections all operate at resonance. Frequency modulation is accomplished without the use of varactors or other voltage-controlled tuning devices.

Abstract: A variable frequency oscillator circuit comprising a resonator circuit part and an amplifier circuit part. The resonator circuit part has a first end and a second end, and it comprises a parallel connected inductor-capacitance pair. The amplifier circuit part comprises first and second transistors having a collector, base, and emitter. The amplifier circuit part further comprises a first impedance matching element connected between the base of the second transistor and the first end of the resonator circuit part, and a second impedance matching element connected between the base of the first transistor and the second end of the resonator circuit part. The impedance matching elements are inductors, namely the third inductor and the fourth inductor. The application of the inductors provides a noise-matched optimum source impedance for the active amplifier circuit part.

Abstract: A segmented inductor for use with a tuning circuit, a method of increasing a self-resonant frequency of a tuning circuit and an oscillator employing the circuit and method. In one embodiment, the tuning circuit includes a first inductive element having a first intrinsic shunt capacitance. The tuning circuit also includes a second inductive element, coupled in series with the first inductive element, having a second intrinsic shunt capacitance. The first and second inductive elements cooperate to reduce a total shunt capacitance associated therewith thereby increasing a self-resonant frequency of the tuning circuit.

Abstract: An LC oscillator capable of oscillating even if it is fabricated on a substrate comprises a transistor, capacitor, and an inductor element 30. The inductor element 30 has two spiral conductors 120, 122 having substantially the same shape and formed on a semiconductor substrate 110. The inner end of the conductor 120 is electrically connected to the outer end of the conductor 122. Lead wires 130, 132 are connected to the outer and inner ends of the conductor 120 respectively. The lead wire 132 is passed through the lower conductor 122 and the semiconductor substrate 110 and led outside. The upper A conductor 120 serves as an inductor conductor and is connected to another component of the LC oscillator formed on the semiconductor substrate 110 through the lead wires 130, 132.