Class / Patent application number | Description | Number of patent applications / Date published |
331109000 | Amplitude stabilization and control | 34 |
20080238559 | Voltage controlled oscillator - A voltage controlled oscillator circuit comprises a variable current generator to supply an operation current to a voltage controlled oscillator, the voltage controlled oscillator to include a resonance circuit having a variable capacitor and inductor, and to output an output signal having an amplitude based on a current generated by the variable current generator, and a first optimization circuit to which the output signal is inputted, the first optimization circuit generating and outputting a current setting signal based on an amplitude change of the output signal corresponding to a change of a current outputted by the variable current generator to the variable current generator. | 10-02-2008 |
20080246547 | Method And System for Output Matching of Rf Transistors - A high frequency power device ( | 10-09-2008 |
20080266006 | VOLTAGE CONTROLLED OSCILLATOR WITH SWITCHING BIAS - Provided is a voltage controlled oscillator to which a switching bias technique is applied so as to lower flicker noise of a bias circuit and enhance phase noise characteristics, thereby reducing the overall chip area to make it possible to achieve integration. A common mode voltage applied to the bias circuit is negatively fed back to an oscillation waveform. Therefore, it is possible to stabilize the magnitude of the oscillation waveform of the voltage controlled oscillator with respect to a change in an external condition. | 10-30-2008 |
20090033432 | OSCILLATION DRIVER DEVICE, PHYSICAL QUANTITY MEASURING DEVICE, AND ELECTRONIC INSTRUMENT - An oscillation driver device includes a gain control amplifier, an automatic gain control circuit, and a mode setting circuit. When the mode setting circuit has switched a mode from a normal operation mode to a low power consumption mode, the automatic gain control circuit is disabled, and the gain in an oscillation loop that drives the vibrator changes from a state in which the gain in the oscillation loop is controlled to be unity by the automatic gain control circuit to a state in which the gain in the oscillation loop is set to be larger than unity. When the mode setting circuit has switched the mode from the low power consumption mode to the normal operation mode, the automatic gain control circuit resumes operation, and the gain in the oscillation loop changes from the state in which the gain in the oscillation loop is set to be larger than unity to the state in which the gain in the oscillation loop is controlled to be unity by the automatic gain control circuit. | 02-05-2009 |
20090085680 | OSCILLATOR GENERATING NORMAL CLOCK SIGNAL - Disclosed is an oscillator including a reference voltage generator generating a reference voltage, and a logic combination circuit generating complementary first and second internal clock signals in response to the reference voltage and complementary first and second output voltages. One of the first and second output voltages—the one going high—is provided to the logic combination circuit before the other one of the first and second output voltages—the one going low. | 04-02-2009 |
20090146748 | Amplitude Controller for a Clock, Frequency Reference, and Other Reference Signal Generator - Exemplary embodiments of the invention provide a reference signal generator, system and method. An exemplary apparatus to generate a harmonic reference signal includes a reference resonator, such as an LC-tank, and an amplitude controller. The reference resonator generates a first reference signal having a resonant frequency, and the amplitude controller maintains substantially constant a magnitude of a peak amplitude of the first reference signal. A common mode controller may also be included to maintain substantially constant a common mode voltage level of the reference resonator. A temperature-dependent control voltage also may be generated and utilized to maintain the resonant frequency substantially constant or within a predetermined variance of a calibrated or selected frequency. | 06-11-2009 |
20090273405 | ARCHITECTURE FOR MAINTAINING CONSTANT VOLTAGE-CONTROLLED OSCILLATOR GAIN - A voltage controlled oscillator and a method of operating a voltage-controlled oscillator are disclosed. The oscillator comprises a current controlled oscillator having a variable frequency current output, a first control path for generating a first control current having a first adjustable gain, and a second control path for generating a second control current having a second adjustable gain. A summer is provided for adding the first and second control currents to obtain a summed control current, and for applying the summed control current as an input current to the current controlled oscillator. A control sub-circuit is used for controlling the gain of the first control current as a function of a defined voltage on the second control path to maintain constant the gain of the current output of the current controlled oscillator over a given operating range of the current controlled oscillator. | 11-05-2009 |
20090284320 | CLOCK GENERATOR - This invention discloses a clock generator capable of automatically adjusting output clock when process, voltage, or temperature variation occurred. The clock generator comprises a current generator, for generating a first current and a second current according to a control voltage; a oscillator, coupled to the current generator, for generating a clock signal according to the first current; and a voltage adjuster, coupled to the current generator and the oscillator, for adjusting the control voltage according to the clock signal and the second current; wherein, when the signal frequency of the clock signal changed, the voltage adjuster correspondingly adjusts the control voltage so as to adjust the first current. | 11-19-2009 |
20100001804 | SYSTEM TO IMPROVE A VOLTAGE-CONTROLLED OSCILLATOR AND ASSOCIATED METHODS - A system to improve a voltage-controlled oscillator may include a voltage-controlled oscillator. The system may also include a switch to control a first voltage passing through the voltage-controlled oscillator based upon a digital tune bit used to control the voltage-controlled oscillator's gain. | 01-07-2010 |
20100127786 | LOW NOISE OSCILLATORS - An oscillator having: a transistor; a resonant circuit coupled between an output electrode of the transistor and a control electrode of the transistor; and a dc bias circuit for the transistor. The dc bias circuit comprises: a voltage producing circuit and a differential amplifier. The differential amplifier includes: a first input coupled to a fixed reference voltage; a second input coupled to the voltage producing circuit, such voltage producing circuit producing a voltage at the second input of the difference amplifier related to current passing through the output electrode of the transistor; and an output coupled to the control electrode of the transistor. | 05-27-2010 |
20100171561 | OSCILLATOR - An oscillator including: a first complementary differential amplifier (CDA) outputting a first output signal obtained by amplifying signals input to a first input terminal and a second input terminal of the first CDA; and a second CDA outputting a second output signal obtained by amplifying signals input to a first input terminal and a second input terminal of the second CDA, the second output signal having a differential phase with respect to the first output signal, wherein the first CDA may include an output terminal connected to the first input terminal and the second input terminal of the second CDA and the second CDA may include an output terminal connected to the first input terminal and the second input terminal of the first CDA. | 07-08-2010 |
20110001571 | CRYSTAL OSCILLATOR EMULATOR - A crystal oscillator emulator integrated circuit includes a first temperature sensor configured to sense a first temperature of the crystal oscillator emulator integrated circuit. The memory is configured to (i) store calibration parameters and (ii) select at least one of the calibration parameters based on the first temperature. A semiconductor oscillator is configured to generate an output signal, wherein (i) the output signal has a frequency and an amplitude and (ii) the frequency is based on the at least one of the calibration parameters. An amplitude adjustment module is configured to (i) compare the amplitude to a predetermined amplitude and (ii) generate a control signal to adjust the amplitude based on the comparison. | 01-06-2011 |
20110095833 | FLEXIBLE LOW CURRENT OSCILLATOR FOR MULTIPHASE OPERATIONS - A method for generating an oscillator signal uses a multiphase oscillator having a plurality of input stages and a reference stage. Each input stage produces an input stage voltage that represents a phase for the oscillator. The input stage voltages produced by each of the input stages are compared to a reference voltage produced by the reference stage. An input stage having a maximum input stage voltage is selected and an output of the selected input stage having the maximum input stage voltage is changed. A current need of the oscillator is detected with a negative feedback loop coupled to the reference stage. An appropriate supply current is provided to each input stage with the negative feedback loop. | 04-28-2011 |
20110187468 | LOW HEADROOM OSCILLATOR - A low headroom oscillator operates at low supply voltages without the use of monostable circuits or flip flops. The oscillator operates in multiple states which allow for the charging and discharging of the capacitors alternately to enable the proper operating of the oscillator at low supply voltages without locking up. | 08-04-2011 |
20110309888 | TECHNIQUE FOR LINEARIZING THE VOLTAGE-TO-FREQUENCY RESPONSE OF A VCO - Apparatuses and methods are provided relating to a voltage controlled oscillator (VCO) based on current starved inverting delay stages; wherein in each stage a PMOS transistor as header and an NMOS transistor as footer are used with their gate-to-source voltages always equal to analog control voltage. The analog control voltage is also used as the supply voltage of the oscillator. An exemplary apparatus includes a VCO of n stages, where n is an odd number and where each stage includes a current starved inverter where the analog control voltage is also used as the supply voltage of each delay stage. | 12-22-2011 |
20110316638 | DELAY-LINE SELF-OSCILLATOR - An electrical, magnetic or electromagnetic delay line self oscillator is described with a delay line arrangement, an oscillator control circuitry, and a frequency selection impedance connecting the delay line arrangement and the oscillator control circuitry and presenting an impedance to the delay line arrangement. The oscillator control circuitry includes an amplifier, a non linear amplitude control element (N-LACE) such as an active device with a negative differential conductance that provides an output amplitude has a negative second derivative with respect to an input signal, and a driver. The modal characteristics of electromagnetic delay lines can thus be exploited across a wide range of instrumentation applications, and a means is provided to enhance the achievable functionality and/or performance of the instrumentation without the need for expensive additional electrical hardware or electronics. | 12-29-2011 |
20120092079 | OSCILLATOR CIRCUIT AND METHOD OF IMPROVING NOISE IMMUNITY - Noise immunity of an oscillator circuit is improved by either increasing the oscillation amplitude of the core's oscillating signal or configuring a built-in low pass filter. | 04-19-2012 |
20120223783 | OSCILLATOR CIRCUIT AND ELECTRONIC APPARATUS INCLUDING THE SAME - An amplifier circuit for amplifying output signal from the crystal oscillator circuit is connected to the output side of the crystal oscillator circuit. The amplifier circuit amplifies the difference between the output voltage of the crystal oscillator circuit and the input voltage of a CMOS inverter of the crystal oscillator circuit. For example, a differential amplifier is connected to the output side of the crystal oscillator circuit, then the output voltage of the crystal oscillator circuit and the input voltage of the CMOS inverter are connected to the inputs of the differential amplifier. | 09-06-2012 |
20120242418 | VOLTAGE-CONTROLLED OSCILLATING CIRCUIT AND CRYSTAL OSCILLATOR - A voltage-controlled oscillating circuit includes a differential amplifying circuit connected to a resonant element such as a quartz crystal element. The differential amplifying circuit includes first and second input terminals connected to the resonant element and also connected respectively to first and second voltage-controlled capacitors. The differential output terminals of the differential amplifying circuit are connected respectively to first and second emitter follower circuits. The output signal of the first emitter follower circuit is fed back to the second input terminal through a third capacitor and a third voltage-controlled capacitor, and the output signal of the second emitter follower circuit is fed back to the second input terminal through a fourth capacitor and a fourth voltage-controlled capacitor. A control voltage is applied to each of the voltage-controlled capacitors. | 09-27-2012 |
20120242419 | OSCILLATOR AND CONTROL CIRCUIT THEREOF - An oscillator and a control circuit thereof are provided. The control circuit is configured to control an oscillator to adjust the amplitude and the level of an oscillation signal. The control circuit includes a peak amplitude detector, an average voltage detector, and an oscillation controller. The peak amplitude detector is configured to detect the amplitude of the oscillation signal, so as to generate an amplitude value. The average voltage detector is configured to detect the direct current (DC) level of the oscillation signal, so as to generate an average value. The oscillation controller is configured to generate two power signals according to the amplitude value and the average value. The two power signals are provided to the oscillator, so that the oscillator adjusts the amplitude and DC level of the oscillation signal. | 09-27-2012 |
20120274409 | INJECTION LOCKING BASED POWER AMPLIFIER - A method, an apparatus and/or a system of injection locking based power amplifier is disclosed. A method includes inputting a reference signal through an injection circuit of an oscillator circuit that generates an output signal of high power that oscillates at an inherent frequency of oscillation of the oscillator circuit. The method also includes reducing a frequency of the reference signal through a differential transistor pair coupled to the injection circuit of the oscillator circuit. The method further includes locking through a tuning circuit of the oscillator circuit coupled to the differential transistor pair a frequency of the output signal to the reduced frequency of the reference signal based on the power of the reference signal to amplify the power of the reference signal through the oscillator circuit. The frequency of the reference signal is higher than the frequency of the output signal. | 11-01-2012 |
20120306583 | APPARATUS AND METHOD FOR OSCILLATOR RESONATOR POWER CONTROL - Embodiments of the present invention provide an oscillator having circuitry that measures the power dissipated in a resonator and circuitry that controls the power delivered to the resonator in response to the measured power. In some embodiments, the circuitry that measures the power dissipated in the resonator comprises circuitry that measures the voltage across the resonator, circuitry that measures the current through the resonator, and circuitry that calculates the power dissipated in the resonator based on the measured voltage and current. | 12-06-2012 |
20130033333 | SELF CALIBRATED, BROADBAND, TUNABLE, ACTIVE OSCILLATOR WITH UNITY GAIN CELLS FOR MULTI-STANDARD AND/OR MULTIBAND CHANNEL SELECTION - An oscillator includes N greater than unity gain amplifiers, N being at least two. Each of the N greater than unity gain amplifiers has a pair of differential input terminals and a pair of differential output terminals. The oscillator further includes a first pair of variable resistances, N−1 pairs of variable resistances, N−1 pairs of variable capacitances, and a variable capacitance. The pairs of variable resistances couple differential output terminals of the N greater than unity gain amplifiers. The pairs of variable capacitances couple differential input terminals of the N greater than unity gain amplifiers. Each of the N greater than unity gain amplifiers includes a linearized operational transconductance amplifier stage coupled to a corresponding pair of the differential input terminals, and a unity gain buffer with feedback interconnected between the linearized operational transconductance amplifier stage and a corresponding pair of the differential output terminals. | 02-07-2013 |
20130249640 | LOCAL OSCILLATOR (LO) DRIVER CIRCUIT FOR A MIXER - An improved local oscillator (LO) driver circuit for a mixer, the LO driver circuit includes a gain circuit responsive to response to LO input signals at a predetermined LO frequency range. At least a first pair of a parallel combination of a resistor and a capacitor is coupled to the gain circuit and to LO inputs of the mixer. The resistor configured to increase impedance at low frequencies of the frequency range and the capacitor is configured to reduce the impedance of the first parallel combination at high frequencies of the frequency range to reduce resistive impendence of the resistor. At least a second pair of a parallel combination of a low quality inductor and a high quality inductor is connected to the first pair. The second pair in serial combination with the first pair is tuned to provide a constant desired load impedance and a constant desired voltage swing at the LO inputs of the mixer over the predetermined LO frequency range. | 09-26-2013 |
20130257550 | CIRCUIT DEVICE, OSCILLATION DEVICE, AND ELECTRONIC APPARATUS - A circuit device includes a current supply circuit adapted to supply an oscillation current, an oscillation circuit having an oscillation transistor for a resonator, and adapted to drive the resonator using the oscillation transistor based on an oscillation current from the current supply circuit, and a control section adapted to control the current supply circuit. If the oscillation circuit is set to an overdrive mode, the oscillation circuit drives the resonator with a higher drive power than the drive power in a normal mode. | 10-03-2013 |
20140070897 | OSCILLATOR CIRCUIT - An oscillator circuit ( | 03-13-2014 |
20140091869 | Method and Apparatus of a Crystal Oscillator with a Noiseless and Amplitude Based Start Up Control Loop - A large gain is used to start up the oscillation of the crystal quickly. Once the oscillation starts, the amplitude is detected. A control circuit determines based on the measured amplitude to disable a low resistance path in the controlled switch array to reduce the applied gain below the power dissipation specification of the crystal. Another technique introduces a mixed-signal controlled power supply multi-path resistive array which tailors the maximum current to the crystal. A successive approximation register converts the amplitude into several partitions and enables/disables one of several power routing paths to the inverter of the oscillator. This allows a better match between the crystal selected by the customer and the on-chip drive circuitry to power up the oscillator without stressing the crystal. The “l/f” noise of the oscillator circuit is minimized by operating transistors in the triode region instead of the linear region. | 04-03-2014 |
20140132362 | SELF-POWERED CRYSTAL OSCILLATOR AND METHOD OF GENERATING OSCILLATION SIGNAL - A self-powered power crystal oscillator XO includes a crystal unit and a power injection module. The crystal unit is arranged to oscillate to generate an oscillation signal. The power injection module is coupled to the crystal unit, and is arranged to intermittently inject energy to the crystal unit. | 05-15-2014 |
20140176248 | USE OF ELECTRONIC ATTENUATOR FOR MEMS OSCILLATOR OVERDRIVE PROTECTION - An apparatus includes a microelectromechanical system (MEMS) device configured as part of an oscillator. The MEMS device includes a mass suspended from a substrate of the MEMS, a first electrode configured to provide a first signal based on a displacement of the mass, and a second electrode configured to receive a second signal based on the first signal. The apparatus includes an amplifier coupled to the first electrode and a first node. The amplifier is configured to generate an output signal, the output signal being based on the first signal and a first gain. The apparatus includes an attenuator configured to attenuate the output signal based on a second gain and provide as the second signal an attenuated version of the output signal. | 06-26-2014 |
20140253251 | MULTI-POWER MODE REFERENCE CLOCK WITH CONSTANT DUTY CYCLE - A power management apparatus and method for maintaining a substantially constant duty cycle of a reference clock signal in a multi-power oscillator, includes a first output power transistor in electrical parallel with a series arrangement of a second output power transistor and a switch, and a crystal oscillator capacitively coupled to a common gate of the first and second output power transistors, wherein a level of the reference clock signal power output is a normal power level when the switch is open and the level of the reference clock signal power output is a higher power level when the switch is closed to operate the second output power transistor in parallel with the first output power transistor. | 09-11-2014 |
20140375391 | VOLTAGE CONTROLLED OSCILLATOR - Disclosed is a voltage controlled oscillator which includes a first transistor in which a first terminal is connected to a first power supply, a body is connected to a gate, and a first output signal is output through a second terminal; a second transistor that is cross-coupled to the first transistor in such a manner that a first terminal is connected to the first power supply, a body connected to the second terminal of the first transistor is connected to a gate, and a second terminal is connected to the body of the first transistor, and that outputs a second output signal having an opposite phase to that of the first output signal through the second terminal; and a resonance filter in which a first terminal is connected to the second terminal of the first transistor and a second terminal is connected to the second terminal of the second transistor. | 12-25-2014 |
20150070100 | SEMICONDUCTOR INTEGRATED CIRCUIT AND OSCILLATION SYSTEM - The semiconductor integrated circuit includes an inverting amplifier that generates an oscillation signal with an input connected to the first terminal and an output connected to the second terminal, the inverting amplifier fluctuating in gain in response to a gain control signal. The semiconductor integrated circuit includes a waveform shaping circuit that shapes a waveform of the oscillation signal and outputs a clock signal to a clock signal output terminal. The semiconductor integrated circuit includes an edge detecting circuit that detects an edge of the clock signal and outputs the gain control signal at a time of the edge. | 03-12-2015 |
20150109064 | AUTOMATIC AMPLITUDE CONTROL CIRCUIT - The present invention provides an automatic amplitude control circuit, including an oscillator, a collecting module, a first analog current generating module, a second analog current generating module, and a numerical control current generating module. According to this automatic amplitude control circuit, a low-noise numerical control bias current can be provided for the oscillator. | 04-23-2015 |
20150137898 | Oscillator Buffer and Method for Calibrating the Same - A buffering circuit for buffering an oscillator signal. The buffering circuit includes a plurality of PMOS and NMOS transistor pairs connected in parallel, each pair having connected gate terminals and connected drain terminals forming an inverter circuit, each pair arranged for receiving via a direct coupling an oscillator signal at its gate terminal, and each pair further being connected with an additional PMOS and NMOS transistor. The buffering circuit also includes a control circuit arranged for receiving an output signal provided by the inverter circuits, for deriving information on the DC level of the output signal, and for adjusting a voltage transfer curve expressing a relationship between a voltage at the input and output of the buffering circuit, by switching on or off the additional PMOS and NMOS transistors based on the derived information | 05-21-2015 |