Abstract: A charge pump power supply includes two or more modes of operation. An input protection circuit is connected between an input of the power supply and a voltage source. The input protection circuit regulates the voltage at the input of the power supply, limits current at the input when switching from a weaker mode to a stronger mode, and prevents current reversal when switching from a stronger mode to a weaker mode. In some modes, the power supply continuously provides current to the load, obviating the need for an output capacitor.

Abstract: The problem of undesired power consumption in an oscillator during “stop” periods of a device is addressed by providing the oscillator in apparatus external to the device, the apparatus including a current sensor sensing current in a line between the apparatus and the device, the line communicating an oscillator “clock” signal. If the device enters a “stop” state the current flow during certain half-cycles of the oscillation is relatively low compared to the current flow in the “no-stop” state. In response to the relatively low current, the apparatus halts oscillation. Later, when the device exits the “stop” state, current flow increases in the line, and the apparatus resumes oscillation, thereby resuming the communication of the clock signal to the device.

Abstract: A ripple-mode controller provides reliable operation in multi-phase power supply circuits, over a variety of operating conditions. Cross-phase blanking allows the controller to preserve the desired phase relationship between the switching pulses its provides to the different output phases, and permits the controller to operate each output phase at nearly 100% duty cycles. Active current sharing compliments blanking operations by adjusting the width of switching pulses the controller provides to one or more of the output phases based on detecting load current imbalances between the different output phases. With active current sharing, the controller prevents one or more output phases from carrying excessive portions of the load current. Further complimenting its operation, the controller may include virtual ripple generation to increase the noise immunity of its ripple-mode regulation.

Abstract: Apparatus and method are disclosed for receiving human input by means of a pointing device, typically a strain gauge. Three dimensions of input are received from a resistor bridge by means of four contact points to the strain gauge. A sequence of excitation signals is applied to the bridge and a multiplexer is employed to permit a signal processor to sample sensor outputs. The apparatus processes the sampled outputs and determines the user inputs such as X and Y and Z values of the pointing device.

Abstract: An improvement to a phase and frequency detector (PFD) employs an additional reset control that acts to effectively reset the registers that generate the phase indicator signals if an undesirable preconditioned state has been entered. The additional reset control signal is generated by a register that is enabled upon detection of the preconditioned state. The new reset control signal is activated upon detection of a synchronizing signal, that is based on an input source signal, while the enable control is active. The improved detector can allows a phase locked loop (PLL) system locking to the nearest input reference clock edge and it can provide immunity to missing input clock edges.

Abstract: A voltage positioning technique allows a power supply controller to more fully exploit active voltage positioning as a way of maintaining supply voltage within the limits defined for an associated electrical load. The supply voltage is allowed to “droop” as a function of load current. Droop may be implemented in linear proportion to load current, or as a discrete droop function once load current exceeds a given threshold. In either case, the droop circuitry of the supply controller implements a bounding function that establishes an accurately known maximum droop voltage magnitude. This maximum droop voltage limit establishes a reliable lower limit for the supply voltage independent of increasing load current. This accurately set lower bound for the droop voltage enables the controller to more aggressively position the supply voltage at the lower voltage limit of the load, which minimizes voltage overshoot and load power consumption.

Abstract: A swinging inductor is used to achieve zero-current switching in a resonant buck-type voltage converter. The swinging inductor exhibits the property of a relatively high inductance at zero current and low current, but it swings back to the original resonant inductance value at high current. In this way the high and medium regions of the current sine wave remain effectively unchanged. Upon circuit power application, the current rises slowly due to the high swinging inductance value, but this is an innocuous parasitic effect. Using the swinging inductance placed in series with a switching device to control the transfer of energy from the input source to the output load allows for a very efficient transfer of energy and it also prevents the current from becoming negative. Moreover, the efficiency level is sustainable over a wide range of input and output voltage requirements.

Abstract: A multiphase controller for a PWM power converter employs a single current sense device to measure input current, I, and an integrator at each phase to accurately measure power delivered during a pulse. The integrator monitors current delivered through a circuit which delivers a current signal scaled to I/N where N is the number of active phases. Thus where there are three overlapping phases, one-third of I is delivered to the integrator for each phase that is on or active. The integrator provides a Charge Ramp signal to an input of a Pulse Width Modulation (PWM) comparator associated with each phase. The other input of the PWM comparator is tied to an error control signal common to all of the phases. When the Charge Ramp signal and the error control signal match, the corresponding phase is turned off for the duration of the cycle.

Abstract: A current sense circuit for a DC-to-DC power converter accurately senses the output inductor current without adversely affecting efficiency of the power converter. The current sense circuit produces a current sense signal having amplitude sufficiently above the noise floor so that accurate load control of the power converter is achieved. Specifically, the DC-to-DC power converter includes at least one power switch connected to an input voltage source. At least one phase sensing switch is connected to the input voltage source in parallel with the at least one power switch. A pulse width modulation circuit provides common control pulses for the at least one power switch and the at least one phase sensing switch responsive to a current sense signal. An output inductor is connected to the at least one power switch and to a load.

Abstract: A clock output controller using a digital frequency synthesis minimizes the clock output disturbance due to input reference signal switchover. The controller includes a first and a second accumulator where the Most Significant Bit (MSB) of the first accumulator output generates the clock output signal and the MSB of the second accumulator generates a feedback signal. A reset control signal is generated by the transition edge detector/switchover controller and it is coupled to the register block of the second accumulator in order to reset the feedback signal at an appropriate time so as to match the phase of the new reference signal. A hold control signal is also generated to keep the clock output locked on the old reference signal until the feedback signal is locked to the new signal. The hold signal is then reset once locking to the new reference signal is accomplished and the clock output is fully switched over with minimal disturbance.

Abstract: An apparatus and method for accurately sensing the output current delivered to a load by a buck-type DC-to-DC switched mode power converter corrects for thermal variation of the output inductor. A first current sense signal provides a fast indication of output current of the DC-to-DC converter that is susceptible to thermal variation of the output inductor of the converter, and a second current sense signal provides a slow but accurate indication of output current that is not affected by said thermal variation. The first current sense signal is corrected using the second current sense signal to yield accurate output current sensing information. In an embodiment of the invention, an output current sensing apparatus is provided for use in a multi-phase DC-to-DC voltage converter comprising a plurality of converter modules connected to a common load and having a common input voltage source.

Abstract: A multi-phase power supply utilizes a current sensor including a sensor inductor winding connected in parallel with a filter inductor winding at the output of each phase for sensing the phase currents and balancing the current by adjusting the duty cycle of each phase through feedback control. In addition, in a multi-module power supply configuration, current between power supply modules is balanced through use of the same current sensor and current sharing technique. Each phase of the power supply includes at least one input power source and a current sensor. The sensor inductor winding and the filter inductor winding have the same number of turns and are wound about a magnetic core also present at each phase. A differential amplifier at each phase senses and amplifies any voltage difference between the outputs of the sensor inductor winding and the corresponding filter inductor winding.

Abstract: An apparatus and method for virtual current sensing in a DC-DC switched mode power supply. In a fixed frequency implementation, when a switching phase begins, the phase node goes high when the high-side switching transistor is turned on. At this point, a first programmable current source begins charging a current sensing capacitor and the voltage across the capacitor simulates the rising slope of the voltage across a conventional current sensing resistor. Simultaneously, a ramp capacitor beginning at a reference voltage is charged by a second programmable current source. When the sum of the voltages across the two capacitors exceeds an error voltage, the phase node goes low when the drive signal to the transistor is turned off. At this point, a third programmable current source begins discharging the current sensing capacitor and the voltage across the capacitor simulates the falling slope of the current across the conventional resistor.

Abstract: A step-down switched-mode power supply circuit includes a transformer having at least one primary winding and at least one secondary winding, a current sensing device for sensing a current through a primary winding of the transformer, a first switch and a second switch, a first comparator for determining if the current through the current sensing device exceeds a threshold, a voltage regulator coupled to the secondary winding to produce a regulated voltage, a second comparator for determining if the regulated voltage has drooped below an acceptable level, a counter coupled to the second comparator for generating a signal having a fixed number of switch cycles, and control circuitry for generating signals controlling the first switch and the second switch and responsive to the first comparator to enter a power saving mode disabling the signals, and to the second comparator to temporarily exit the power saving mode for a fixed number of cycles when the regulated voltage has drooped below an acceptable level.

Abstract: A current sensing device incorporated into the gate charge current path of the power transistor in a typical pulse-width modulated current mode switching power supply controller provides adaptive leading edge blanking of the current-sense waveform present in the feedback signal to prevent erroneous response in the feedback control circuitry and improve regulation of the power supply output voltage. A serial switch located within the current-sense feedback signal path is directly controlled by the current sensing device to open and close the signal path and generate a blanking interval which is optimally aligned to blank out or remove the leading edge spike in the current-sense waveform which corresponds to the gate charge current pulse that occurs during the turn-on transition of the power transistor.

Abstract: A multi-phase power supply utilizes a current sensor including a sensor inductor winding connected in parallel with a filter inductor winding at the output of each phase for sensing the phase currents and balancing the current by adjusting the duty cycle of each phase through feedback control. In addition, in a multi-module power supply configuration, current between power supply modules is balanced through use of the same current sensor and current sharing technique. Each phase of the power supply includes at least one input power source and a current sensor. The sensor inductor winding and the filter inductor winding have the same number of turns and are wound about a magnetic core also present at each phase. A differential amplifier at each phase senses and amplifies any voltage difference between the outputs of the sensor inductor winding and the corresponding filter inductor winding.

Abstract: A nonlinear transconductance provides a nonlinear output in response to a differential signal input. In a switch-type closed loop system, such as switching mode DC—DC converter of phase lock loop, the nonlinear transconductance amplifier provides a very fast response time. The nonlinear transconductance amplifier is a linear transconductance amplifier that has been modified to include a nonlinear output stage of current mirrors having resistive elements connected to the emitters of the diode connected transistors in the current mirrors.

Abstract: A switched mode DC-DC power converter of the flyback type includes a primary circuit and a secondary circuit capacitively coupled to one another. In a first aspect the primary includes circuitry for achieving a 2:1 current transfer gain over the input, in a second aspect the secondary includes circuitry for achieving a 2:1 current transfer gain over an input. Combined, a 4:1 current transfer gain may be realized.

Abstract: A fast buffer and switching regulator are combined in parallel in a master-slave loop topology to form a voltage regulator. The buffer circuit has a voltage sensing amplifier that senses the difference between the voltage at the output of the voltage regulator and a reference voltage. This voltage difference is amplified, and then input to a buffer that sources current to or sinks current from the output of the voltage regulator. The output of the buffer circuit is coupled to the switching converter which senses the changing buffer circuit output current. The switching converter changes its duty cycle to oppose the current from the buffer circuit. This is a master-slave loop topology wherein the buffer circuit is the master loop that quickly provides high levels of current to compensate for a voltage transient at the output of the voltage regulator, and the switching converter is the slave loop which eventually takes over from the master loop to meet the current output requirements of the voltage regulator.

Abstract: A slave clock generation system and method suitable for use with synchronous telecommunications networks generates one or more slave clocks from a selected reference clock using a direct digital synthesis technique. A multiplexer selects a reference clock from a number of available sources, each of which can be at its own spot frequency, based on a predetermined selection order. Toggle detectors monitor each of the available clock sources, and block the selection of any that are not within a specified frequency range. A local oscillator establishes short-term and long-term measurement periods; the cycles of the selected reference clock are counted over consecutive short-term measurement periods to determine the relative frequency of the selected clock with respect to the frequency of the local oscillator. The cycle counts are fed to a phase-to-clock converter, which produces a slave clock output having a frequency that varies with the relative frequency measured for the selected clock.