Abstract: A frequency discriminator comprising a power splitter for splitting a signal into first and second paths, wherein the first path is configured to provide a first, straight-through signal and the second path includes a frequency-dependent element, such as low-pass filter, so as to provide a second signal. The frequency discriminator further comprises a circuit configured to compare the first and second signals and generate an instantaneous frequency signal in dependence thereon.

Abstract: An envelope detector circuit, suitable for use in RFID tags, includes a voltage doubler circuit and a biasing voltage generating circuit which comprises components matched respectively to rectifying components of the voltage doubler circuit. A rectifying component of this voltage doubler circuit is formed by a transistor controlled by the biasing voltage generating circuit which provides a biasing voltage to a control gate of this transistor, the biasing voltage generating circuit being arranged so as to permit a determined forward biasing current to flow through the transistor and further rectifying elements of the voltage doubler circuit. This embodiment provides fast, highly sensitive detection of envelope waveforms in input signals. Thanks to the matched rectifying components, efficiency variations due to variations in manufacturing process can be eliminated. The envelope detector circuit is further arranged for maintaining a stable detection independent of variations in temperature.

Abstract: A serial data transmission system, includes a transmitting terminal for transmitting a data, a receiving terminal for receiving the data transmitted by the transmitting terminal, a first connecting capacitor connected between the transmitting terminal and the receiving terminal, and a second connecting capacitor connected between the transmitting terminal and the receiving terminal, wherein the transmitting terminal comprises a transmitting terminal driver unit and an amplitude detection unit connected with the transmitting terminal driver unit, the transmitting terminal driver unit outputs a pair of differential signals, the amplitude detection unit detects an amplitude variation of the differential signals output by the transmitting terminal driver unit, and outputs an indication signal indicating whether the transmitting terminal and the receiving terminal are properly connected with each other. A serial data transmission method is further provided.

Abstract: A zero bias power detector comprising a zero bias diode and an output boost circuit is provided. The output boost circuit comprises a zero bias transistor. The zero bias diode is not biased but outputs a rectifying signal according to a wireless signal. The zero bias transistor, not biased but coupled to the zero bias diode, is used for enhancing the rectifying signal.

Abstract: A voltage amplitude limiting circuit of a full differential circuit is provided for limiting voltage levels of a differential signal. The voltage amplitude limiting circuit includes a reference voltage generating unit and a replacing circuit. The reference voltage generating unit generates a high reference voltage and a low reference voltage. The replacing circuit is coupled to the reference voltage generating unit, a first input terminal and a second input terminal. When voltage at the first input terminal is greater than the high reference voltage, the replacing circuit uses the high reference voltage to replace the voltage at the first input terminal to serve as an output. When voltage at the first input terminal is less than the low reference voltage, the replacing circuit uses the low reference voltage to replace the voltage at the first input terminal to serve as an output.

Abstract: A receiving circuit with a simple circuit structure for performing wireless communication utilizing electromagnetic induction is provided. An LSI chip and a storage medium where wireless communication utilizing electromagnetic induction is performed and the circuit scale and circuit size can be reduced are provided. The following receiving circuit may be used: a parallel circuit where two diode elements whose directions are opposite are connected in parallel is used, one end of the parallel circuit is connected to the other end of a coil whose one end is connected to a ground potential line, and a capacitor is connected in series with the other end of the parallel circuit. A transistor whose leakage current is markedly reduced may be used as a diode in the receiving circuit. Such a receiving circuit may be used in an LSI chip or a storage medium.

Abstract: A device for use with an RF generating source, a first electrode, a second electrode and an element. The RF generating source is operable to provide an RF signal to the first electrode and thereby create a potential between the first electrode and the second electrode. The device comprises a connecting portion and a current sink. The connecting portion is operable to electrically connect to one of the first electrode, the second electrode and an element. The current sink is in electrical connection with the connection portion and a path to ground. The current sink comprises a voltage threshold. The current sink is operable to conduct current from the connecting portion to ground when a voltage on the electrically connected one of the first electrode, the second electrode and the element is greater than the voltage threshold.

Abstract: Provided are transmitter topology, receiver topology and methods for generating and transmitting a radio signal at a transmitter and detecting and processing a radio signal at a receiver. The radio signals are transmitted across a wireless interface using Ultra Wideband (UWB) pulses. A transmitted reference approach is utilized. The radio signal include pairs of UWB pulses with each pair of pulses separated by a fixed time delay. The two pulses are then combined to provide for improved noise immunity.

Abstract: A device for detecting the peak value of a signal with crest factor not known a priori includes a pair of peak detectors, each of which includes a rectifier element and a discharge-current generator and generates a respective output signal that is a function of the ratio between a physical dimension of the rectifier element and the intensity of discharge current produced by the generator. The ratio is different for the two detectors, and a combination network combines the output signals of the two peak detectors with one another and produces a combined signal indicating the peak value sought with high accuracy.

Abstract: A circuit comprises a control line and a two terminal semiconductor device having first and second terminals. The first terminal is coupled to a signal line, and the second terminal is coupled to the control line. The two terminal semiconductor device is adapted to have a capacitance when a voltage on the first terminal relative to the second terminal is above a threshold voltage and to have a smaller capacitance when a voltage on the first terminal relative to the second terminal is below the threshold voltage. The control line is coupled to a control signal and the signal line is coupled to a signal and is output of the circuit. A signal is placed on the signal line and voltage on the control line is modified (e.g., raised in the case of n-type devices, or lowered for a p-type devices). When the signal falls below the threshold voltage, the two terminal semiconductor device acts as a very small capacitor and the output of the circuit will be a small value.

Abstract: A power detection system is disclosed that includes a detector circuit and a comparator circuit. The detector circuit includes a first transistor, a second transistor that is not identical to the first transistor, and a third transistor that is substantially identical to the first transistor. Each of the transistors is commonly coupled to a current source and is coupled to a differential input voltage. The comparator circuit is for providing an output that is representative of whether the input voltage is above or below a threshold voltage responsive to a difference between the first transistor and the second transistor.

Abstract: A detection circuit includes a bias circuit configured to generate a first bias voltage and a second bias voltage. The detection circuit further includes a storage device configured to store a detection value corresponding to an amplitude of a radio frequency signal received at a detector input. A series connection of a first diode element and a second diode element includes first tap to receive the first bias voltage and the radio frequency signal, a second tap which is coupled to a connection node of the first and the second diode element to receive the second bias voltage and a third tap to provide the detection value.

Abstract: A device for detecting the peak value of a signal with crest factor not known a priori includes a pair of peak detectors, each of which includes a rectifier element and a discharge-current generator and generates a respective output signal that is a function of the ratio between a physical dimension of the rectifier element and the intensity of discharge current produced by the generator. The ratio is different for the two detectors, and a combination network combines the output signals of the two peak detectors with one another and produces a combined signal indicating the peak value sought with high accuracy.

Abstract: An envelope detecting circuit is provided. The envelope detecting circuit comprises a source degeneration circuit that amplifies an input differential signal, a differential gain stage that supplies a voltage proportional to the amplified signal, a potential hold circuit that holds the voltage supplied from the gain stage, a comparator circuit that compares the voltage held by the potential holding circuit with a reference potential to output a detect signal, and envelope level adjustment and selection unit that responds to the detect signal and outputs a control signal to the source degeneration circuit.

Abstract: A peak detector circuit that responds rapidly to power transients, and yet is able to avoid interpreting data fluctuations as power transients by generating dual peak signals from an amplifier's differential output signal, where the dual peak signals have data ripple components that tend to cancel one another. The system and methods permit the peak detectors to be much more responsive to power transients by expanding their bandwidth (shortening the time constants) to the point that low frequency data components affect the individual peak detector signals, but the effects are cancelled out when the individual components are added together. The peak detector described herein may be used in an AGC system to provide ripple-free gain control signals, while rapidly following any power transients in transmitted signals.

Abstract: Aspects of the present invention include a method, apparatus and device for generating a power on reset (POR) signal in relation to the crossing point of two currents wherein at least one current is a quadratic function and the other is an exponential function, where each has a mathematical correlation to a function of a predetermined power supply voltage.

Abstract: A peak detector provides repeatable and accurate measurements of the signal amplitude for variable frequencies of input signals. The peak detector includes a pulse edge generator circuit that generates a pulse edge signal in response to the signal peaks of an input signal and a sampler circuit that is triggered to sample the input signal by the pulse edge signal. The pulse edge generator circuit compares the input signal with a delayed version of the input signal to produce a differential signal and generates the pulse edge signal using the differential signal. An analog or digital sampler is triggered by the pulsed edge signal to measure the information, e.g., peak value, of the input signal. One or more delay circuits may be used to align the edges of the pulsed edge signal with the peaks of the input signal.

Abstract: Systems and methods for determining a slicing level which is used as a threshold to determine whether timeslots of an incoming data signal contain ones or zeros. The method of one embodiment comprises receiving a data signal, identifying a maximum level of the data signal, identifying a minimum level of the data signal, determining an average of the minimum and maximum levels, and then using the average of the minimum and maximum levels as a slicing level to identify bits of a data packet embodied in the data signal.

Abstract: Method and apparatus for providing a peak detection circuit comprising a diode including an input terminal and an output terminal the input terminal of the diode configured to receive an input signal, a capacitor operatively coupled to the output terminal of the diode, an output terminal operatively coupled to the capacitor and the output terminal of the diode for outputting an output signal is provided. Other equivalent switching configuration is further provided to effectively detect and compensate for a voltage droop from a power supply signal, as well as to electrically isolate the voltage droop from the system circuitry.

Abstract: A delayed peak detector detects a peak level of an input signal IN at timing lagged behind a peak detector, and a peak difference detector detects a peak difference PLD between a delayed peak level DPL and a peak level PL. A reset portion outputs a reset signal BRS for a bottom detector when a level difference between the peak level PL and a bottom level BL exceeds a predetermined value comparable with the amplitude of the input signal IN and the peak difference PLD exceeds an allowable peak difference PLM. It is thus possible to replace the bottom level BL outputted from the bottom detector with a bottom level based on a latest input signal IN.

Abstract: A circuit configuration which includes an input circuit referenced to one ground voltage and an output circuit referenced to another ground voltage capacitively coupled to the input circuit.

Abstract: A peak detector is provided. Current switches are utilized and controlled by output of a plurality of error amplifiers respectively, such that charging currents are adjusted for a charge element in response to operations of the current switches respectively. Therefore, the overshooting charge is avoided and the time for charge is optimized.

Abstract: The present invention is a quadrature RF power detector circuit, which is used in conjunction with a quadrature RF power amplifier to detect and combine RF signals from an in-phase amplifier leg and from a quadrature-phase amplifier leg to provide an RF power detection signal. The quadrature RF power detector circuit includes an emitter follower amplifier for each leg of the quadrature RF power amplifier and may include doubler circuitry to detect both half-cycles of an RF signal. The emitter follower detector provides power detection with minimal DC current and without significant RF loading at the point of detection, such as an RF interstage. This balanced detector also provides more accurate power detection under high VSWR conditions due to the quadrature action minimizing peaks and valleys in the detected voltage.

Abstract: An RF envelope detection circuit that operations at low currents, high sensitivity, and high dynamic range. The circuit receives an AC signal at its input terminal and applies a signal on its output terminal that is a function of the envelope magnitude of the AC signal. To do so, a current source provides a current with an AC signal being superimposed thereon. A rectification circuit rectifies the AC component of this current. A voltage amplifier then amplifies the voltage for providing on the output terminal of the detection circuit. A current sink draws a current from the output terminal that has approximately the same magnitude as the current provided by the current source. A capacitor is coupled to the output terminal of the rectifier so as to store excess charge provided by the rectifier that is in excess of the magnitude of the current provided by the current source.

Abstract: A programmable capacitor array does not require separate switching transistors because the capacitors themselves have a switchable capacitance, which capacitors are made in the manner of regular N channel transistors with their source/drains connected to each other. When a logic low is applied to the gate, the capacitance is relatively low and the capacitance is what is commonly called parasitic capacitance. The capacitance increases significantly when a logic high is applied to the gate because the logic high has the effect of inverting the channel. Thus, the capacitor array is made of transistors that themselves have switchable capacitance operated so that no separate switching transistors are required. This allows for construction of an array of unit capacitors to achieve monotonic operation and good linearity using conventional manufacturing of N channel transistors while achieving significant area savings and reduced power consumption.

Abstract: A sense amplifier circuit comprises (1) an isolation device comprising a control terminal and first and second terminals, the first terminal of the isolation device coupled to a signal line, (2) a gated diode comprising first and second terminals, the first terminal of the gated diode coupled to the second terminal of the isolation device, and the second terminal of the gated diode coupled to a set line; and (3) control circuitry coupled to the control terminal of the isolation device and adapted to control voltage on the control terminal of the isolation device in order to enable and disable the isolation device. A latch circuit further comprises a precharge device comprising a control terminal and first and second terminals, the first terminal of the precharge device coupled to a power supply voltage, and the second terminal of the precharge device coupled to the first terminal of the isolation device.

Abstract: A sense amplifier circuit comprises (1) an isolation device comprising a control terminal and first and second terminals, the first terminal of the isolation device coupled to a signal line, (2) a gated diode comprising first and second terminals, the first terminal of the gated diode coupled to the second terminal of the isolation device, and the second terminal of the gated diode coupled to a set line; and (3) control circuitry coupled to the control terminal of the isolation device and adapted to control voltage on the control terminal of the isolation device in order to enable and disable the isolation device. A latch circuit further comprises a precharge device comprising a control terminal and first and second terminals, the first terminal of the precharge device coupled to a power supply voltage, and the second terminal of the precharge device coupled to the first terminal of the isolation device.

Abstract: A transmit and receive protection circuit for use in a communication system is disclosed. The protection circuit uses a four-diode gate in which the currents through an input portion and an output portion of the diode gate are individually controlled by resistors located in their respective portions. This arrangement allows the DC currents through each portion to be independently controlled. By using resistors to independently control the DC currents through each portion of the diode gate, better control over the individual DC currents can be achieved, leading to effective AC resistances which are more predictable. This arrangement results in a predictable low loss protection circuit at a minimal expense.

Abstract: A regulator circuit capable of reducing an increase in an output voltage during a sudden drop in a load current without increasing the power consumption during a steady state. When a current in load IL1 changes suddenly from a large current to a minute current during a steady state, electric charges are charged in capacitor CL1 due to a response delay of the negative feedback control, and an output voltage becomes higher than a target voltage. Then, voltage of node N34 drops, diode 31 gets turned off, and a voltage is held in capacitor 32. As a result, output of comparator 42 changes from a low level to a high level, and n-type MOS transistor 82 gets turned on. In addition, when the voltage between the gate and the source of n-type MOS transistor 50 becomes lower than the voltage of voltage source 71 due to a drop in the voltage of node N34, comparator 72 is also reverted to the high level.

Abstract: A low read current, low power consumption sense amplifier well suited for low frequency RFID systems is disclosed. An MOS transistor receives the read current from a memory cell, typically an EEPROM, and a current mirror is formed by a parallel MOS transistor. The mirror current is integrated on a capacitor after the charge on the capacitor is cleared via a reset pulse. A time period is defined during which the voltage on the capacitor is compared to a second voltage. The second voltage is formed from a reference voltage or from dummy cells, in either case the reference voltage is at about the logic boundary between a one and zero stored in a memory cell. A comparator, with or without input hysteresis, receives the voltage on the capacitor and a second voltage and within the time period, the output state of the comparator indicates the binary contents of the memory cell.

Abstract: A comparator is provided with a pair of transistors which are continuously in ON state, in which a switch unit constructed of a diode pair, for switching a current path in response to a high/low relationship between a voltage level of an input signal and a voltage level of a reference voltage, and a unit for converting a current into a voltage level are provided between emitter terminals of the transistor pair.

Abstract: A peak detector employs switched capacitor filtering to implement long time constant and variable attack and decay characteristics. In one embodiment, the peak detector includes a first switch, a rectifier, a first capacitor and a second switch in the attack path, and a third switch, a second capacitor and a fourth switch in the decay path. The peak detector further includes a third capacitor coupled to the attack and decay paths and having a capacitance greater than the capacitance of the first and second capacitors. In operation, the attack path is activated by alternately closing the first and second switches to sample the input signal and generate an output voltage at the third capacitor indicative of the peak voltage value of the input signal. The second circuit path is activated by alternately closing the third and fourth switches to decrease the output voltage at the third capacitor.

Abstract: An envelope detector circuit for use in controlling a RF amplifier is provided. The envelope detector circuit includes a first semiconductor device having a first input port that receives a first input signal and a first output port that provides current to charge a capacitor in response to the first input signal. The envelope detector circuit additionally includes a first current drain coupled to the first semiconductor device and the capacitor, where the first current drain conducts current away from the capacitor. The envelope detector circuit further includes a second semiconductor device having a second input port that is set to a biasing voltage and a second output port that is coupled to the first output port of the first semiconductor device.

Abstract: A device and method for correcting the baseline wandering of transmitting signals are disclosed. The present method and device are used to correct the baseline wandering of the first output terminal and the second output terminal of a receiver as a result of induction effect of the transformer. The present device comprises a compensation current source including a first compensation output terminal and a second compensation output terminal which are respectively connected to the first output terminal and the second output terminal of the receiver. The device further includes a voltage signal generator for generating a control voltage to control the compensation current source. The voltage signal generator employs the voltage difference of the first output terminal and the second output terminal of the receiver and a reference voltage to control the control voltage.

Abstract: A peak detector comprises a device for storing a value representing the currently detected peak amplitude (Cp,Cn), a circuit for detecting whether the input signal amplitude exceeds the stored value (D1 to D4), an apparatus for updating the stored value at a fast rate if the input signal amplitude exceeds the stored value by more than a given value (D1/V1, D3/V4), and an apparatus for updating the stored value at a slow rate if the input signal amplitude exceeds the stored value by less than the given value (D2/R2, D3/R3). Analogue and digital versions are described together with their application to data slicers in, for example, teletext decoders.

Abstract: A controlled detector circuit for generating a detector current to the input of a selected circuit. An unwanted operational voltage is generated on the input of the selected circuit affecting the precision of the detector circuit. The controlled detector circuit comprises a detector circuit having an RF input for detecting a RF signal and a detector output for providing the detector current. Operation of the detector circuit generates a voltage drop affecting the precision of the detector current. A control circuit having a control output connected to the detector output generates a control voltage for reducing the unwanted parameters affecting the precision of the detector current.

Abstract: It is an object of the invention to provide a peak detector with improved precision for low amplitude AC signals for a broad range of input frequencies.

Abstract: A power level sense circuit which is substantially immune to variations in integrated circuit processing and operating temperature. The sense circuit uses a diode biased to a predetermined average conduction level as the primary element in an envelope detector to detect the envelope of the RF transmit signal. While the DC offset of the diode will vary with temperature and integrated circuit processing, the DC offset is eliminated by an auto zeroing procedure before each power sensing cycle.

Abstract: A circuit arrangement is disclosed which detects a signal pauses in an audio signal, The audio signal is amplified, rectified, and then sent to a control unit. The control unit periodically sets the output of the rectifier to a predetermined level below a threshold level. The control unit then waits a predetermined period of time and determines whether the signal at the output of the rectifier has exceeded the threshold. If is does not, a signal pause has occurred.

Abstract: An enhanced peak detector circuit for the amplitude demodulation of an incoming amplitude modulated signal is provided. In its simplest form, the enhanced peak detector circuit includes a forward biased NPN transistor, a peak detecting segment coupled to the base-emitter junction of the transistor; and a peak holding capacitor leading from the collector of the transistor and connected in parallel to the peak detecting segment. The peak detecting segment includes a parallel connected peak detecting capacitor and a resistor. When the base-emitter junction of the transistor is conducting, both the peak detecting capacitor and the peak holding capacitor are charging. Conversely, when the base-emitter junction of the transistor is back biased, the peak detecting capacitor discharges through the resistor and the collector remains open such that the peak holding capacitor remains charged.

Abstract: A circuit that can switch between a peak detect and an averaging mode is described. In a preferred embodiment, when the circuit is in a peak detect mode a first transistor is on and a second is off, enabling an amplifier in the circuit to produce a signal representative of the peak value of an input signal. In an averaging mode, the first transistor is off, and a second transistor turns on, disabling the output of the amplifier, and thus enabling the averaging mode components of the invention.