Switching regulators with ripple-based control (ie, ?ripple regulators?) are conceptually simple, have fast transient responses to both line and load perturbations, and some versions operate with a switching frequency that is proportional to the load current under the discontinuous conduction mode These characteristics make the ripple regulators well-suited, especially for power management applications in computers and portable electronic devices Ripple regulators also have some drawbacks, including (in some versions) a poorly defined switching frequency, noise-induced jitter, inadequate dc regulation, and a tendency for fast-scale instability This paper presents an overview of the various ripple-based control techniques, discusses their merits and limitations, and introduces techniques for reducing the noise sensitivity and the sensitivity to capacitor parameters, improving the frequency stability and the dc regulation, and avoiding fast-scale instability

Ripple-Based Control of Switching Regulators—An Overview

A wireless power transfer system includes a power receiver (105) and a power transmitter (101) generating a wireless inductive power transfer signal for powering the power receiver (105) during a power transfer phase. An apparatus, often the power transmitter (101) comprises a first communication unit (305) communicating with a second communication unit of an entity using an electromagnetic communication signal. The entity may typically be the power receiver (105). The apparatus comprises a reference processor (307) for measuring and storing a reference value of a characteristic of the communication signal and a measurement unit (309) which repeatedly during the power transfer phase determines a measured value of the characteristic. A comparator (311) compares the measured values to the reference value and an initiator (313) triggers an entity detection process if the comparison indicates that a measured value and the reference value do not meet a similarity criterion. The entity detection process detect a presence of another entity.

Wireless inductive power transfer

This disclosure provides systems, methods and apparatus for detecting foreign objects. In one aspect an apparatus for detecting a presence of an object is provided. The apparatus includes a resonant circuit having a resonant frequency. The resonant circuit includes a sense circuit including an electrically conductive structure. The apparatus further includes a coupling circuit coupled to the sense circuit. The apparatus further includes a detection circuit coupled to the sense circuit via the coupling circuit. The detection circuit is configured to detect the presence of the object in response to detecting a difference between a measured characteristic that depends on a frequency at which the resonant circuit is resonating and a corresponding characteristic that depends on the resonant frequency of the resonant circuit. The coupling circuit is configured to reduce a variation of the resonant frequency by the detection circuit in the absence of the object.

Systems, methods, and apparatus for detection of metal objects in a predetermined space

Electrochemical sensing of biomolecules eliminates the need for the bulky and expensive optical instrumentation required in traditional fluorescence-based sensing assays. Integration of the sensor interface electrodes and active electrochemical detection circuitry on a CMOS substrate miniaturizes the sensing platform, enhancing its portability for use in point-of-care applications, while enabling the high-throughput, highly parallel analysis characteristic of traditional microarrays. This paper describes the design of a four-by-four active sensor array for multiplexed electrochemical biomolecular detection in a standard 0.25-mum CMOS process. Integrated potentiostats, comprised of control amplifiers and dual-slope analog-to-digital converters, stimulate the electrochemical cell and detect the current flowing through the on-chip gold electrodes at each sensor site that results from biomolecular reactions occurring on the chip surface. Post-processing steps needed to fabricate a biologically-compatible surface-electrode array in CMOS that can withstand operation in a harsh electrochemical environment are also described. Experimental results demonstrating the proper operation of the active CMOS array for biomolecular detection include cyclic voltammetry of a reversible redox species, DNA probe density characterization, as well as quantitative and specific DNA hybridization detection.

Active CMOS Sensor Array for Electrochemical Biomolecular Detection

The embodiment relates to a wireless power transmission apparatus and a wireless power transmission method The wireless power transmission apparatus includes a first power converting unit to generate high-frequency AC signals; a second power converting unit to generate low-frequency AC signals; a first coil receiving the high-frequency AC signals and transmitting a wireless power through a first power transmission scheme; a second coil receiving the low-frequency AC signals and transmitting the wireless power through a second power transmission scheme; and a control unit to control the first and second coils, wherein the control unit is configured to transmit a detection signal for the first power transmission scheme to a wireless power reception apparatus through the first coil, detect a reception of a first response signal corresponding to the first detection signal during a first predetermined time, determine a power transmission scheme of the wireless power reception apparatus as the first power transmission scheme in response to a detection of the first response signal, and deactivate the first power converting unit in response to no detection of the first response signal

Wireless power transmission apparatus and wireless power transmission method

A synthetic ripple regulator for a DC-DC converter generates an auxiliary voltage waveform that effectively replicates the waveform ripple current through an output inductor, and uses the auxiliary voltage waveform to control toggling of a hysteretic comparator. In a non-limiting implementation, a transconductance amplifier monitors the voltage across the inductor, and supplies an inductor voltage-representative current to a ripple waveform capacitor, so as to produce the auxiliary voltage waveform. Using the replicated inductor current for ripple regulation results in low output ripple, input voltage feed forward, and simplified compensation.

Synthetic ripple regulator

A DC-to-DC converter has a pulse width modulator PWM) and a hysteretic (ripple) modulator. For low current loads, the hysteretic modulator is selected; for high current loads, the PWM is selected. A mode selection switch senses the polarity of the switched output voltage at the end of each switching cycle. If the polarity changes from one cycle to the next, the mode may be instantly changed to the other mode. Counters are used to record the polarity at the end of each cycle and switching from one mode to another can be delayed by the counters to prevent changing modes based on spurious output voltage fluctuations.

Dc to DC converter method and circuitry

We demonstrate a family of wireless power devices that operate in a variety of operating modes. A multimode wireless power receiver unit (PRU) allows a mobile device to charge from any one of three wireless power standards: Qi, Power Matters Alliance, or Rezence. A coil arrangement and matching network is introduced that is resonant in both 6.78-MHz and 100-kHz bands, allowing the same power conversion circuitry to operate in either mode. The multi-mode PRU converts 5 W of ac power to a regulated 5-V output with an efficiency of up to 83% in Rezence mode and up to 86% in Qi mode. A wireless charging power transfer unit (PTU) using the Rezence specification charges three such PRUs at a power level of 5 W each with a power transfer efficiency of 66%. An in-band communications protocol provides enhanced capabilities to the Rezence system. Multiple layers of encoding ensure reliable delivery of messages under difficult channel conditions. Another PTU design allows the same receiver to charge through a table of 30-mm thickness while maintaining the in-band communications link. We show that a wide variety of multimode devices are possible, enabling widespread adoption of wireless power even in the absence of a single unified standard.

Wireless Power Systems for Mobile Devices Supporting Inductive and Resonant Operating Modes

A DC/DC converter (100) has a DAC (40) that receives a code associated with desired processor operating voltage and sets the reference voltage on its output (41). The reference voltage (VDAC) is boosted by the buffer amplifier (42) to center the droop along the median load. A sensed current signal ICS (22) is proportional to the load current IO (24) and can be either inductor current, or switch current, or diode (or synchronous switch) current. In all cases it is scaled down by the factor of gain GC. A droop control feedback circuit includes an error amplifier (50). It has two inputs. In one embodiment the gain of the converter is by a signal inversely proportional to the processor clock frequency FCPUmax and transformed to the current IDROOP (32) amplifier output. As a result, the output voltage of the converter (50) is inversely proportional to the load current and is invariant to the processor clock frequency changes associated with the processor mode switchover.

Methods to control the droop when powering dual mode processors and associated circuits

A wireless power receiver receives electrical power via electromagnetic field coupling from a wireless power transmitter. During communication time periods, the power receiver alters the electromagnetic field in a manner that the power transmitter can detect as a string of logic bits in a communication bit stream for sending data to the power transmitter. During pause time periods when data is not being sent to the power transmitter, the power receiver alters the electromagnetic field in a manner that the power transmitter does not detect as a string of logic bits (e.g. at a rate outside a communication frequency band). In some embodiments, a ripple is reduced in a voltage produced by the wireless power receiver from the electromagnetic field during the communication and pause time periods.

Vladimir A. Muratov

Papers

Synthetic ripple regulator

Dc to DC converter method and circuitry

Wireless Power Systems for Mobile Devices Supporting Inductive and Resonant Operating Modes

Methods to control the droop when powering dual mode processors and associated circuits

Wireless Power Transmission with Improved Modulation Ripple