Abstract: An electronic device includes an electronic part and a wiring substrate. The electronic part includes a rewiring substrate, a semiconductor chip, and solder bumps arranged in a matrix form. The wiring substrate includes a wire and lands arranged in a matrix form corresponding to the solder bumps. Each of the lands is coupled with corresponding one of the solder bumps so as to form connection portions. The connection portions include nonfunctional connection portions that do not provide an electric connection between the semiconductor chip and the wire. The lands forming the nonfunctional connection portions include a power source land and a ground land arranged next to each other in a row direction or a column direction. The lands that are arranged next to the lands forming the nonfunctional connection portions in the row direction or the column direction are set to signal lands.

Abstract: Recesses are formed on one surface of a substrate. A conductive film covers an inner surface of each of the recesses. This conductive film contacts a bump of a semiconductor device to be inspected and is electrically connected to the bump. It is therefore possible to prevent damages of the bump to be caused by contact of a probe pin.

Abstract: A semiconductor integrated circuit device includes: an inter-equipment authentication section formed on a chip and configured to perform inter-equipment authentication between the inter-equipment authentication section itself and source equipment; a control section formed on the chip and configured to control the inter-equipment authentication, the control section operating when a system clock from an oscillation section is supplied, and being capable of giving instructions to stop the oscillation of the oscillation section; and an oscillation stop canceling section configured to output an oscillation stop canceling signal to restart the oscillation of the oscillation section, based upon whether or not 5 volts of DDC from the source equipment is supplied to an input terminal. The start of the operation of a microcontroller unit on a system on chip is cable of being controlled by the 5 volts of DDC, which are power supply voltage supplied from the source equipment via DDCs.

Abstract: This invention comprises a layout method to effectively protect electronic circuits against soft errors (non-destructive errors) and circuit cells, which are protected against soft errors. The invention applies a layout method to sequential and combinational logic to generate specific circuit cells with netlists and layouts which are hardened against single event generated soft-errors. It also devices methods of how two or more such cells should be laid out and placed relative to each other, in order to have the best global soft-error protection.

Abstract: Embodiments of a circuit for use with an inter-chip connection that has a variable complex impedance (which can be conductive, capacitive or both), a system that includes the circuit, and a communication technique are described. This inter-chip connection may be formed between a microspring or an anisotropic film and a metal connector on or proximate to a surface of a chip. Moreover, the circuit may mitigate signal distortion associated with the variable complex impedance. For example, the circuit may include an internal impedance that is electrically coupled in series with the metal connector, and that has an impedance which dominates the variable complex impedance over a range of operating frequencies. Separately or additionally, the circuit may be adapted to correct for the signal distortion.

Abstract: Some of the embodiments of the present invention provide an integrated circuit device including a first metal interconnect, an end of which is coupled to a core of the integrated circuit device, a second metal interconnect, an end of which is coupled to a first input/output (I/O) pin, and a third metal interconnect configured to be coupled to the first metal interconnect and to the second metal interconnect. Other embodiments are also described and claimed.

Abstract: Provided are an inverter, a method of manufacturing the inverter, and a logic circuit including the inverter. The inverter may include a first transistor and a second transistor having different channel layer structures. A channel layer of the first transistor may include a lower layer and an upper layer, and a channel layer of the second transistor may be the same as one of the lower layer and the upper layer. At least one of the lower layer and the upper layer may be an oxide layer. The inverter may be an enhancement/depletion (E/D) mode inverter or a complementary inverter.

Abstract: An output circuit includes: an NMOS transistor of an output buffer, a transistor ON drive circuit configured to turn on the transistor; a switchable current source configured to turn off the transistor; and a drive control circuit configured to control the transistor ON drive circuit and the switchable current source. The electric charge at the gate terminal of the NMOS transistor of the output buffer is pulled out with the current of the switchable current source at a fixed current value even when the gate voltage of the transistor varies in a range of variations of the threshold voltage Vth of the transistor.

Abstract: An output circuit includes a high-side transistor, a low-side transistor, a gate protection circuit, a level shift circuit, and a pre-driver circuit. The level shift circuit interrupts a current path from an output terminal to the level shift circuit after a predetermined time has passed since the high-side transistor was switched OFF.

Abstract: To provide a frequency conversion device which uses a magneto-resistive device and thereby can correspond to a Si-based MMIC and a GaAs-based MMIC. A frequency conversion apparatus according to the present invention includes: a frequency conversion device made of a magneto-resistive device including a magnetic free layer, an intermediate layer, and a magnetic pinned layer; a magnetic field applying mechanism for applying a magnetic field to the frequency conversion device; a local oscillator for applying a local oscillation signal to the frequency conversion device; and an input terminal electrically connected to the frequency conversion device, and used to input an external input signal.

Abstract: A signal frequency change circuit is presented. The signal frequency change circuit includes a delay line, a detector, a controller, a multiplexer, and an output unit. The delay line delays a clock signal by a first delay time corresponding to a delay control signal to generate a delay signal and delays the clock signal by a second delay time shorter than a first delay time to generate a pre-frequency change clock signal. The detector generates a phase locked completion signal. The controller sequentially shifts the delay control signal and a multiplexing control signal. The multiplexer selects and outputs one of the pre-frequency change clock signals. The output unit generates a frequency change clock signal.

Abstract: Provided is an oscillation frequency control circuit for correcting its frequency, keeping the oscillation frequency stable when self-oscillating, and oscillating with a control voltage generated by making a fixed voltage given from outside variable. In the oscillation frequency control circuit, a CPU selects/outputs the control voltage preferentially according to a command of a control voltage selection. If the command is not given and the level of an outside reference signal detected by a detecting circuit is within an adequate range, it turns a select switch on. If the command is not given and the level of the outside reference signal is out of the adequate range, it turns the select switch off and outputs information about pulse generation stored in a memory to a PWM circuit.

Abstract: A VCO driving circuit and a frequency synthesizer wherein the impedance viewed from a VCO control terminal is reduced to prevent the VCO phase noise characteristic from degrading. A VCO driving circuit and a frequency synthesizer having the VCO driving circuit, which comprises a coarse adjustment DAC that receives a digital data, which has a coarse adjustment frequency, to output an analog signal; a fine adjustment DAC that receives a digital data, which has a fine adjustment frequency, to output an analog signal; a low response speed LPF5 that removes noise from the output signal from the coarse adjustment DAC and then provides the resultant signal as an input to a VCO control terminal; a high response speed LPF7 that converts the output signal from the fine adjustment DAC to a voltage, thereby smoothing the signal; a resistor that connects an input stage of the LPF5 to that of the LPF7; and a capacitor used for providing a capacitive coupling such that the output of the LPF7 is added to that of the LPF5.

Abstract: Disclosed herein is a clock data recovery circuit including: a first phase detector; a loop filter; a charge pump; a voltage-controlled oscillator; a second phase detector; a phase correction information generation section; and a phase correction information addition section.

Abstract: There is provided a PLL circuit including a first loop filter and a second loop filter, which includes a current signal generation circuit that includes a first output driver that generates a first current signal to be output to the first loop filter and a second output driver that generates a second current signal to be output to the second loop filter, and a control circuit that selects which of the first output driver and the second output driver is to be activated.

Abstract: A fractional-N frequency synthesizer having reduced fractional switching noise and spurious signals is provided. The synthesizer includes a voltage controlled oscillator for providing an output signal. A fractional-N divider is responsive to the voltage controlled oscillator for providing a divided output signal having fractional switching noise. A band pass filter is responsive to the fractional-N divider for reducing the fractional switching noise and non-linearities that result in spurious signals. A phase detector is responsive to a reference signal and the band pass filter for providing a control signal representative of the phase difference between the reference signal and the signal from the band pass filter. A loop filter is responsive to the phase detector for filtering the control signal to control the voltage controlled oscillator, the output of the loop filter having reduced fractional switching noise and spurious signals.

Abstract: A semiconductor integrated circuit includes an update control unit configured to generate an update control signal in response to a first command and a second command; and a DLL (Delay Locked Loop) circuit configured to generate an output clock by controlling a phase of an external clock in response to the update control signal.

Abstract: A clock and data recovery (CDR) circuit is provided. The CDR circuit receives a data signal and generates a clock signal. The CDR circuit comprises an oscillator, a phase detector, and a first voltage-to-current (V-to-I) converter. The oscillator generates the clock signal according to an oscillation voltage. The phase detector receives the data signal. The phase detector comprises a mixer for detecting a phase difference between the data clock and the clock signal and generating a phase detection signal which represents the phase difference. The first V-to-I converter receives the phase detection signal and generates a first current signal according to a voltage level of the phase detection signal to vary the oscillation voltage.

Abstract: Provided are a delay locked loop (DLL) having a pulse width detection circuit and a method of driving the DLL. The DLL includes a pulse width detection circuit and a delay circuit. The pulse width detection circuit receives a reference clock signal, detects a pulse width of the reference clock signal, and outputs the detection result as a pulse width detection result signal. The delay circuit receives and delays the reference clock signal, and outputs the delayed reference clock signal as an output clock signal. The delay circuit receives the pulse width detection result signal from the pulse width detection circuit, and controls a time delay in the reference clock signal in response to the pulse width detection result signal.

Abstract: The phase interpolator includes two adjustable delays 30 and 31, phase comparator 32 which detects a phase difference between a signal delayed by the adjustable delay 30 and a signal delayed by the adjustable delay 31, an integrator 33 which integrates the outputs of the phase comparator 32 and multipliers 34-1 and 34-2 which set a control voltage for the adjustable delays 30 and 31. The feedback loop comprising phase comparator 32 and integrator 33 controls a delay amount of the adjustable delay 30 thereby securing a phase relation between {ACK1, ACK2} and ICK to achieve a stable ICK phase.

Abstract: Consistent with an example embodiment, an edge-rate control circuit arrangement (300) for an I2C bus application comprises a first circuit stage (10, M1, M3), responsive to a state transition of a received signal. A second circuit stage (310, 25, 20, 35, 45, M4, ESD) is responsive to the state transition of the received signal and includes drive circuitry (M4) that is activated in response to the state transition of the received signal in order to provide an edge-transition signal for an I2C bus, and regulation circuitry (310, R1, R2, M0, M2) adapted to control the drive circuit and regulate a transition rate for the edge-transition signal, the transition rate being greater than a transition rate of the received signal at the first circuit stage and greater than a minimum and less than a maximum transition rate designated for communication on the I2C bus.

Abstract: A data signal generation device comprising a microprocessor and a digital potential divider, in which the microprocessor is adapted to generate a square wave output signal, and in which the digital potential divider is adapted to receive said square wave output signal, and to ramp up and down an output signal voltage and/or current according to state transitions in said square wave output signal.

Abstract: A flip-flop structure with reduced set-up time is provided. The flip-flop includes the first master latch receiving a function data through the first switch controlled by a clock signal, the second master latch receiving a scan data through the second switch controlled by the clock signal, and a slave latch connected to the first master latch through the third switch controlled by the clock signal. The second master latch is coupled to the first master latch through the fourth switch controlled by the scan enable signal so that the scan enable signal controls whether the function data or the scan data becomes an output from the first master latch to the slave latch, and the slave latch is used to latch and transmit the output from the first master latch.

Abstract: A system includes an input device, an output device, a mechanical chassis, a printed circuit board, and a semiconductor device. The semiconductor device includes a mechanical package, and a semiconductor die. The semiconductor die includes a semiconductor layer, a plurality of metal layers, a clock distribution network that distributes a clock signal within the die, and an economy precision pulse generating circuit. The economy precision pulse generating circuit includes a pre-charge circuit, a gate-to-the-partial-jam-latch-keeper circuit, a partial-jam-latch-keeper circuit, and a pull-down-against-the-up-keeper circuit. A source clock signal is derived from the clock signal. The source clock signal is provided to a first input of a logical AND circuit, the pre-charge circuit, and the gate-to-the-partial-jam-latch-keeper circuit. A common storage node is connected to a second input of the logical AND circuit. The logical AND circuit outputs an output pulse.

Abstract: A cascoded input-output device is provided configured to receive at an input node a lower voltage input signal and to generate at an output node a higher voltage output signal. The input-output device is split into two voltage domains to enable output signals in a larger range to be generated, whilst the components of the input-output device individually operate in a smaller range. By applying a selected bias voltage to a protected node of the cascoded input-output device, first changing that selected bias voltage in response to a transition of the input signal and then switching that selected bias voltage back when the output signal reaches a predetermined level, that node is protected, either avoiding stress-inducing voltage swings or providing a switching speed increasing charge boost.

Abstract: In one embodiment, a level shifter circuit is provided that may include approximately matched rising edge and falling edge delays through the level shifter. The level shifter may also have a low delay and low power consumption. The level shifter circuit may include a pair of low voltage input inverters coupled to a pulldown transistor, where a node between the low voltage input inverters is coupled through another pulldown stack to a pullup transistor. Including an output inverter, both rising transitions and falling transitions may include about 4 gate delays in one embodiment. The level shifter may include keeper transistors to turn off the pullup transistor after the pullup is performed, and the pulldown transistor may be turned off as the pullup transistor is turned on. The pullup and pulldown transistors may not drive against each other during operation, which may reduce power consumption in the circuit.

Abstract: An apparatus is disclosed for receiving input signals in a first higher voltage domain and for generating and outputting signals in a second lower voltage domain, said apparatus comprising: an input pad for receiving said input signals in said first higher voltage domain; output circuitry comprising a plurality of devices arranged between a high voltage source of said second lower voltage domain and a low voltage source, said plurality of devices being arranged in a first set and a second set, said first set being arranged between said high voltage source and said output and said second set being arranged between said output and said low voltage source, said output circuitry being configured to switch to output a first predetermined value in response to a rising input signal exceeding an upper threshold value and to switch to output a second predetermined value in response to a falling input signal falling below a lower threshold value; a first input path for sending said received input signals to a first inp

Abstract: A cascoded level shifter for receiving an input signal in a low voltage range and for generating an output signal in a high voltage range is disclosed.

Abstract: System for converting a radiofrequency signal SRX so as to recover encoded information carried by the signal SRX, includes generating elements arranged to generate a signal SLO, mixing elements (3) arranged to generate a signal SRX-LO by mixing the signal SRX with the signal SLO, an analog/digital converter arranged to convert the signal SRXLO into a digital signal SRX-LO-Num, a device generating an error correction digital signal SCor, the device being arranged so that the signal SCor reflects the phase gap between the phase of the signal SLO and a phase setpoint, the phase setpoint being the phase of an ideal signal S0, ideal for recovering the encoded information carried by the signal SRX, combining elements arranged to generate the signal S0?Num by combining the signal SRX-LO-Num with the signal SCor. A system for converting a digital signal so as to send a radiofrequency analog signal carrying the information of the digital signal is also described.

Abstract: In a mixer circuit, addition of analog signals by capacitive coupling is used and square-law characteristics of the drain current of a MOS transistor operating in a saturated region are used. With this configuration, the voltage and power of the mixer circuit can be reduced.

Abstract: A temperature-compensated voltage comparator (301) that compares first and second input voltages includes first and second bipolar junction transistors (BJTs) (221 and 222) that convert the first and second input voltages to first and second input currents, respectively. The first and second BJTs share a same thermal environment and their currents are dependent upon temperature. A temperature-compensating circuit (350), which includes a zero thermal coefficient reference (419), generates a logarithmic temperature-compensating factor that compensates for temperature dependency of the first and second BJTs. The temperature-compensating circuit receives one of the input currents, and outputs a temperature-compensated current that is said input current multiplied by the logarithmic temperature-compensating factor. The temperature-compensating circuit shares a thermal environment with the first and second BJTs.

Abstract: With conventional charge pumps, significant noise is present due at least in part to large changes in the supply current. To combat this problem, a charge pump is provided that includes a number of stages. These stages are coupled to receive periodic alternating voltages having a phase shift with respect to each other so that the changes in the supply current are reduced, which reduces noise.

Abstract: A method of masking a current requirement of an electronic circuit (100) is provided, wherein the method comprises determining a current level required by the electronic circuit (100) and a corresponding point in time said current level is required by the electronic circuit (100), choosing a current level corresponding to a current level which is equal or higher than the determined current level, and switching a current level supplied to/consumed by the electronic circuit (100) to the chosen current level at a time instant deviating from the determined point in time.

Abstract: Various embodiments of the present invention provide systems and methods for governing power dissipation in a semiconductor device. For example, various embodiments of the present invention provide semiconductor devices that include a first function circuit, a second function circuit, and a power state change control circuit. The power state change control circuit is operable to determine a combination of power states of the first function circuit and the second function circuit that provides an overall power dissipation within a power dissipation level.

Abstract: A system and method for over-voltage protection of a power amplifier is provided. A power amplifier is typically employed in a transmitter to amplify signals prior to transmission via a load; the load may include an antenna or a cable. As a result of an impedance mismatch between the power amplifier and its load, excess power from the power amplifier output fails to reach the load and must be dissipated by one or more transistors in the power amplifier. In severe impedance mismatch conditions, this dissipated power may damage or destroy the transistor(s). An automatic gain control (AGC) is provided for detecting a gain difference between the power amplifier and a replica power amplifier. A gain difference may signal an over-voltage situation. The AGC may be configured to adjust the gain of the power amplifier if a gain difference exists to prevent device damage.

Abstract: The present invention discloses a Class-D power amplifier and control method thereof. In one embodiment, the amplifier feeds back the signal at the output node to the inverting input of the comparator, and provides a high frequency triangular wave signal to the non-inverting input of the comparator. In addition, the non-inverting input of the comparator may be coupled to an offset voltage, while the inverting input of the comparator may be coupled to a fixed-frequency rectangular wave signal, a feedback signal which is derived from the output stage and an input signal. In use, the switching frequency may be at least substantially fixed, so as to reduce the influence on the system caused by electromagnetic interruption (EMI). Further, the control circuit is simple, and some devices can be integrated.

Abstract: The present invention comprises class AB amplifier systems exhibiting low quiescent power, low-voltage operation, high gain, high bandwidth, low noise and low offset, and requiring a small die area. The amplifier systems use a differential first stage and a second stage of two pair of nested current mirrors interconnected in a particular way. Using a low quiescent current, the present invention reduces power consumption almost to a theoretical minimum. Also the circuit will operate at an input of only 1.8V with a threshold voltage of 1V. Various embodiments are disclosed.

Abstract: An amplifier with bias stabilizer includes first to forth transistors, an amplifier unit and a resistor. The first transistor and the second transistor are connected in series between first and second power supplies and generate a first current. The third transistor is connected in a current mirror configuration to the second transistor and generates a second current corresponding to the first current. The amplifier unit generates an output signal based on an input signal and includes a fourth transistor, the fourth transistor generating a control voltage according to the second current so as to control the first transistor. The resistor is connected in series to at least one of the first to fourth transistors.

Abstract: The present invention relates to a low noise cascode amplifier comprising a first transistor, a second transistor, a third transistor, a first inductor, and a second inductor. Furthermore, the first transistor can connect with the second transistor via the first inductor, and the second transistor can connect with the third transistor via the second inductor; thereby, a cascode device can be formed. The inductor and the parasitic capacitances can resonate at high frequency, so that the noise figure of the cascode amplifier can be reduced.

Abstract: A variable gain amplifier (VGA) disclosed herein includes an input current connector, an output current connector, a gain adjustment connector, scaled current mirrors copying the input current, means for steering the copied currents either to the current output or to another appropriate location based on the signal present at the gain adjustment connector.

Abstract: An amplifying circuit includes: an amplifying unit which amplifies an input signal and applies the amplified signal to a designated load; a current detection unit which detects a load current that flows into the designated load upon application of the amplified signal; an estimating unit which calculates, based on the voltage level of the input signal, an estimated value of the load current to be supplied to the load; and an adjusting unit which adjusts an input bias, to be applied to the amplifying unit, in such a manner so as to reduce a difference value representing a difference between the estimated value and the load current detected by the current detection unit.

Abstract: A voltage converter includes a plurality of capacitors and corresponding first switch elements, the capacitors coupled in series and arranged to each charge to a voltage level during a first clock period, the voltage level determined by a supply voltage level, the number of capacitors and a value of each capacitor; and a plurality of second switch elements configured to cause the plurality of capacitors to be connected in parallel and to discharge into an output capacitor during a second clock period, the output capacitor charged to a discrete voltage output level so that the output capacitor provides the discrete voltage output level, wherein the discrete voltage output level is less than the supply voltage level and wherein the discrete voltage output level is used to develop a bias signal that is supplied to a power amplifier element.

Abstract: An amplifying circuit includes: a waveform modifying unit which changes the signal value in the second section in such a manner so as to reduce the difference between the signal strength of a DC component of the input signal and the limit value that limits the variation range of the signal value in the first section; a DC component removing unit which removes the DC component of the input signal after the input signal has been modified by the waveform modifying unit; and an amplifying unit which amplifies the input signal whose DC component has been removed.

Abstract: A phase locked loop (PLL) with a loop bandwidth calibration circuit is provided. The mixed-mode PLL comprises an analog phase correction path, a digital frequency correction path, a calibration current source, and a loop bandwidth calibration circuit. The analog phase correction path comprises a linear phase correction unit (LPCU). The digital frequency correction path comprises a digital integral path circuit. The calibration current source is coupled to the LPCU. The loop bandwidth calibration circuit is coupled to a frequency divider and coupled between the input and output of the PLL. The loop bandwidth calibration circuit operates after the calibration current source injects a calibration current into the LPCU.

Abstract: An LC oscillator is provided that achieves improved phase noise performance. A variable frequency oscillator includes a variable supply source (I), an oscillator tank circuit (T), a variable capacitance circuit (VC1) comprising MOS switches, and an oscillator tank voltage common mode adjustment circuit (R). When the capacitance of the variable capacitance circuit is varied to vary an output frequency of the variable frequency oscillator, the common mode voltage is adjusted to reduce transitions of the MOS switches between an inversion state and a depletion state during excursions of an output signal through one cycle of oscillation.

Abstract: Circuits for processing radio frequency (“RF”) and microwave signals are fabricated using field effect transistors (“FETs”) that have one or more strained channel layers disposed on one or more planarized substrate layers. FETs having such a configuration exhibit improved values for, for example, transconductance and noise figure. RF circuits such as, for example, voltage controlled oscillators (“VCOs”), low noise amplifiers (“LNAs”), and phase locked loops (“PLLs”) built using these FETs also exhibit enhanced performance.

Abstract: Nth-order voltage- and current-mode arbitrary phase shift oscillator structures are synthesized using n operational trans-conductance amplifiers (OTAs) or second-generation current controlled conveyors (CCCIIs) and n grounded capacitors. Linking up the I/O characteristics of the OTA and the CCCII and the reactance of grounded capacitor, the step of synthesis is first based on the algebraic analysis to oscillatory characteristic equations, resulting in a quadrature oscillator structure. Secondly, instead of the quadrature characteristic, to control each output signal with one another by a desired phase difference > or <90°, selectively superposing any of two fundamental OTA/CCCII-C sub-circuitries benefits the transformation of quadrature to arbitrary-phase-shift characteristic for the sinusoidal oscillator structure. Furthermore, several compensation schemes are presented for reducing the output parameter deviation due to the non-ideal effects.

Abstract: A micromechanical component and a method for providing the oscillation excitation of an oscillation element of a micromechanical component, the micromechanical component having a frame, which is connected to a carrier substrate by an outer suspension element, in which the frame being tiltable about a first axis and oscillatory about a second axis that is positioned perpendicular to the first axis, and in which the micromechanical component having an oscillation element that is connected to the frame by an inner suspension element, and is tiltable about the second axis, the outer suspension element being provided to be dimensioned in such a way that a first oscillation of the frame about the second axis and a second oscillation of the oscillation element about the second axis have a maximum coupling.

Abstract: The invention relates to an apparatus and a method for charge transfer, wherein a charge transfer apparatus (10) in particular comprises: an oscillation generator (20) for production of acoustic oscillations; at least two mutually separated electrode elements (16a, 16h); and a mechanical resonator element (12), which is coupled to the oscillation generator and has at least one charge transfer section (18) which can be moved between the two electrode elements (16a, 16b).

Abstract: An oscillation circuit, a driving circuit thereof, and a driving method thereof are provided. The driving circuit generates a second enable signal according to an output signal of an oscillator and a first enable signal. The second enable signal is transmitted to the oscillator. When a wave number of the output signal is smaller than a predetermined value during a predetermined period, the driving circuit adjusts a voltage level of the second enable signal. A voltage level of the first enable signal is equal to an enable voltage level. Through variations in voltage levels of the second enable signal, the oscillator is triggered to oscillate.