Abstract: The present invention relates generally to systems and methods for detecting ground faults (i.e., line-to-ground faults) in motor drive systems. In particular, the embodiments described herein include a common mode choke of a motor drive system having additional (i.e., secondary) turns wound around a core of the common mode choke. These secondary turns are in addition to and separate from a plurality of sets of primary turns wound around the core of the common mode choke, each set of primary turns corresponding to a phase of AC power to which the common mode choke is directly coupled. The secondary turns terminate in series with a burden resistor. Ground faults may be detected by monitoring the voltage across the burden resistor.

Abstract: The invention relates to a surge arrester which, in a housing (7), has at least one arrester element (3), in particular a varistor, a solder-fixed thermal disconnection point (5), which is connected to the arrester element, and a damage indicating device (11) for displaying the fault state, wherein the damage indicating device also queries the state of a thermal disconnection device, in particular a fuse, and presents the possible fault states of the arrester element and of the disconnection device mechanically in an OR combination in a suitable way. Furthermore the thermal disconnection device comprises a movable component, which is fixed by an indicator wire and is released after the melting or destruction of said wire. According to the invention, a guide part (9) for a compression spring (10) or similar force accumulator is provided on or in the housing.

Abstract: An electrical system includes an alternating current (AC) source; a transformer rectifier unit (TRU) connected to the AC source, the TRU configured to receive AC power from the AC source, convert the AC power to direct current (DC) power, and output DC power; a DC bus configured to receive the DC power output by the TRU; at least one DC load powered by the DC bus; and a shunt regulator connected to the output of the TRU, the shunt regulator configured to overload the output of the TRU in the event of an overvoltage condition at the output of the TRU, such that a voltage available to the DC bus during the overvoltage condition does not exceed a reference voltage.

Abstract: A protection circuit that interrupts a supply of power to a driving circuit for a power conversion apparatus upon detection of an abnormality includes switches connected in series between the power supply and the driving circuit. An interruption signal enabling/disabling circuit controls the transmission of an interruption signal from the power conversion apparatus to one of the switches and turns the switch off. A monitoring circuit monitors a voltage output from the switches, and determines that the switch which is to be turned off is in a short-circuit state if the voltage is a normal value. A switch may also be determined to be in a short-circuit fault state if the interruption signal turns the switches off, and if a monitored voltage output from the switches decreases at a decay rate faster than a decay rate in a condition where the switch is not in a short-circuit state.

Abstract: A battery tester capable of measuring resistance and voltage of a battery using the same input channel. When measuring battery resistance, a testing signal circuit is electrically coupled to two electrodes of a subject battery to conduct a testing signal used in the battery resistance measurement. A response sensing circuit of the battery tester is also electrically coupled to the two electrodes of the subject battery to measure a response signal across the two electrodes of the subject battery. A resistance measuring module is electrically coupled to the response sensing circuit to measure the battery resistance based on the response signal detected by the response sensing circuit. A circuit breaker is capable of disconnecting the subject battery from the testing signal circuit, and disconnecting the resistance measuring module from the response sensing circuit. Moreover, the battery tester can also provide automatic protection for the battery resistance measuring module.

Abstract: A photovoltaic inverter for coupling a direct current photovoltaic source to an alternating current energy grid and performing a low voltage ride through. The inverter includes a power bridge to convert direct current voltage to alternating current voltage. A switching crowbar is coupled to the photovoltaic energy source and the power bridge. The crowbar has a switching device having a closed position causing the switching crowbar to dissipate energy from the photovoltaic energy source and an open position to allow direct output from the photovoltaic source to the power bridge. A voltage sensor detects a low voltage condition on the grid. A controller is coupled to the voltage sensor and controls the switching crowbar when a low voltage condition is detected.

Abstract: Structures and methods are provided for nanosecond electrical pulse anneal processes. The method of forming an electrostatic discharge (ESD) N+/P+ structure includes forming an N+ diffusion on a substrate and a P+ diffusion on the substrate. The P+ diffusion is in electrical contact with the N+ diffusion. The method further includes forming a device between the N+ diffusion and the P+ diffusion. A method of annealing a structure or material includes applying an electrical pulse across an electrostatic discharge (ESD) N+/P+ structure for a plurality of nanoseconds.

Abstract: A data processing device with a power supply and data signal interface circuit has a switch for connecting an external line and an internal node. The power supply and data signal interface circuit also includes a controller for applying an enabling voltage to the switch enabling the switch to supply current between the external line and the internal node in the presence of power supply to the controller and in the absence of the overvoltage condition on the external line. The power supply and data signal interface circuit also includes a voltage reduction connection from the external line for applying a control voltage to the switch in the absence of power supply to the controller. The control voltage from the voltage reduction connection limits a voltage applied to the internal node through the switch in the presence of the overvoltage condition.

Abstract: Provided is an ESD protection circuit for CDM capable of preventing a high current from flowing and preventing breakage when a battery is connected with reverse polarity. The ESD protection circuit employs a circuit configuration in which transistor elements are interposed in series to OFF transistors (11 and 13) included in the ESD protection circuit for CDM so that parasitic diodes of the transistor elements are connected to parasitic diodes of the OFF transistors in a reverse direction.

Abstract: An electrostatic discharge (ESD) protection device electronically connected to a pad is provided. The ESD protection device includes K PNP transistors and a protection circuit, wherein K is a positive integer. An emitter of the 1st PNP transistor is electronically connected to the pad, a base of the ith PNP transistor is electronically connected to an emitter of the (i+1)th PNP transistor, and collectors of the K PNP transistors are electronically connected to a ground, wherein i is an integer and 1?i?(K?1). The protection circuit is electronically connected between a base of the Kth PNP transistor and the ground and provides a discharge path. An electrostatic signal from the pad is conducted to the ground through the discharge path and the K PNP transistors.

Abstract: Aspects of a protection circuit and method are disclosed. A transmit circuit generates a power transmit signal for powering the transmit antenna to generate a wireless field sufficient for wirelessly charging a device. A detection circuit senses a strength of an electromagnetic field received by the transmit antenna and further configured to generate an sense signal indicating the strength of the electromagnetic field received by the transmit antenna. A power control circuit controls a switch based at least partly on the sense signal. The power control circuit can attenuate an electrical coupling between the transmit antenna and the transmit circuit such that the received electromagnetic field is inhibited from damaging the transmit antenna or the transmit circuit.

Abstract: A surge protection device has a pulse controlled switch, a pulse generation circuit and an abnormal voltage detection circuit. The surge control switch is connected in series to a power line loop and has at least one control terminal respectively connected to output terminals of the pulse generation circuit and the abnormal voltage detection circuit. An output terminal of the abnormal voltage detection circuit is connected to the power line loop and is located in the back end of the pulse controlled switch. The pulse generation circuit serves to send a pulse to the pulse controlled switch to close the pulse controlled switch and connect to the power line loop. When continuously detecting abnormal voltage in the power line loop, the abnormal voltage detection circuit opens the pulse controlled switch and disconnects from the power line loop so as to protect back-end equipment or circuit.

Abstract: The present technology discloses a high-voltage device comprising a high-voltage transistor and an integrated over-voltage protection circuit. The over-voltage protection circuit monitors a voltage across the high-voltage transistor to detect an over-voltage condition of the high-voltage transistor, and turns the high-voltage transistor ON when the over-voltage condition is detected. Thus, once the high-voltage transistor is in over-voltage condition, the high-voltage transistor is turned ON and can dissipate the power from the over-voltage event through its channel.

Abstract: The present invention relates to a battery charge/discharge protection circuit that protects an associated battery from charge/discharge damage. The charge/discharge protection circuit includes a first terminal, a second terminal, a charge over-current detection circuit, a discharge over-current detection circuit, a short circuit detection circuit, and a PMOS transistor. A drain electrode and a gate electrode of the PMOS transistor are connected to the first terminal and the second terminal respectively. A source electrode of the PMOS transistor is connected to the charge over-current detection circuit, the discharge over-current detection circuit and the short circuit detection circuit, such that when a voltage above an overvoltage threshold is supported by the charger, the voltage of the source electrode of the PMOS transistor is maintained above a negative threshold voltage and the elements in these circuits do not receive such a voltage output by the charger.

Abstract: An overvoltage protector for an electrical consumer in a motor vehicle, includes an input for connection to the electrical system of a motor vehicle, an output for connection to the electrical consumer to be protected, and a ground terminal which is connected via a line to a branch point between the input and the output, wherein at least one component that blocks below a threshold voltage and conducts above the threshold voltage, and a switch connected in series with the component are located in the line, wherein the switch is controlled by a control circuit that closes the switch when a voltage spike occurs and subsequently reopens it.

Abstract: A circuit protection device includes an overvoltage monitor circuit that is operable to monitor a power supply circuit to detect an overvoltage condition on the power supply circuit and to change a state of an overvoltage output responsive to the overvoltage condition on the power supply circuit. A bi-directional switch is operable to interrupt or limit current flow though the power supply circuit responsive to the change in the state of the overvoltage output. A bi-directional voltage limiter is connected across output terminals of the circuit protection device and is operable to limit an overvoltage to a predefined voltage limit.

Abstract: An overcharge protection device (OPD) is provided that may be used alone, or in combination with conventional charging protection systems, to protect a battery pack from the occurrence of a potentially damaging overcharging event. The OPD is designed to be coupled to, and interposed between, the terminals of the battery pack. During normal system operation, the OPD has no effect on the operation of the charging system or the battery pack. During an overcharging event, if overcharging is not prevented by another conventional system, the OPD of the invention creates a short across the terminals of the battery pack causing a battery pack fuse designed to provide battery pack short circuit protection to blow, thereby interrupting the current path from the charger to the battery pack and preventing the battery pack from being overcharged.

Abstract: A power converter includes a transient voltage protection circuit connected between an input of the power converter and a power stage of the power converter. The transient voltage protection circuit provides a low resistance connection from the input of the power converter to the power stage of the power converter when the input voltage is less than a predetermined threshold, but blocks the input voltage from the power stage when the input voltage is equal to or greater than the predetermined threshold voltage. The power converter may be a boost power converter used in a vehicle to provide power from a main power bus of the vehicle to a subsystem of the vehicle such as an anti-lock brake system.

Abstract: A control signal interface circuit includes a line voltage protection circuit coupled to first and second input terminals. The protection circuit provides an input DC voltage across the input terminals within a predetermined range (i.e., 0-10 Vdc) and prevents the application of an input line voltage (i.e., 347 Vac) across the input terminals. A first current source circuit is coupled to the protection circuit, an isolation circuit is coupled to the first current source circuit and a second current source circuit is coupled to the isolation circuit. The first and second current source circuits collectively provide a linear output DC voltage with respect to the input DC voltage. At least one of the first and second current source circuits include circuitry wherein the linear conversion of the input DC voltage to the output DC voltage is independent of the temperature.

Abstract: A battery energy storage system including a control unit and a plurality of battery units. The battery units are arranged in series, and each battery unit includes a semiconductor switch and a battery module including a plurality of battery cells. Each battery module is connected in series with a respective semiconductor switch, and the control unit is operatively connected to the semiconductor switch and adapted to control the semiconductor switch of every battery unit.

Abstract: Systems and methods for limiting voltage on an auxiliary bus are described. The voltage-limited auxiliary bus may be comprised of a DC auxiliary bus comprised of a positive conductor and a negative conductor; a chopper, wherein the chopper is normally in a non-conducting state; a resistor in series with the chopper, wherein the chopper and the resistor are connected between the positive conductor and the negative conductor of the DC auxiliary bus; and a chopper control, wherein an overvoltage on the DC auxiliary bus causes the chopper control to cause the chopper to begin conducting and the conducting limits the voltage on the DC auxiliary bus and dissipates energy from the overvoltage.

Abstract: A power supply including a switching voltage regulator detects a peak power fault if a peak power limit is exceeded during a switching cycle of the voltage regulator. A second fault condition exists if a second power limit, lower than the peak power limit, is exceeded over a second time period, longer than the first time period. The switching voltage regulator is stopped in response to either the first or the second fault condition. Responsive to the second fault condition, the switching voltage regulator may be stopped until AC power is cycled or until a predetermined time period has elapsed.

Abstract: One embodiment includes an integrated circuit including an input circuit, a first diode including a first anode and a first cathode, with the first cathode coupled to a first voltage, the first anode coupled to the input circuit at a node via a first mechanical switch, a second diode including a second anode and a second cathode, with the second cathode coupled to the node via a second mechanical switch, the second anode coupled to a ground and a resistor coupled to the input circuit between the integrated circuit and the node, wherein in a first mode of operating, the first mechanical switch and the second mechanical switch are conducting, and in a second mode of operating, the first and second mechanical switches are nonconducting.

Abstract: In an embodiment a circuit provides protection against electrostatic discharge (ESD). A shunt device is controlled to provide a current bypass upon the occurrence of an ESD event. A trigger circuit controls operation of the shunt device and includes an inverter and a hysteresis means to prevent oscillation of the trigger circuit. A reference is used to trigger the control circuit and has a time constant associated with it to distinguish between power up events and ESD events.

Abstract: A method of tripping a circuit breaker including sampling an AC line voltage at regular intervals during a first time period to generate a plurality of AC line voltage samples. Each sample of the set of AC line voltage samples is summed to generate a voltage area value. A controller determines whether the voltage area value exceeds a threshold. In response to the voltage area value exceeding the threshold, an amount determined as a function of the voltage area value is added to a count value. The circuit breaker is caused to trip in response to the count value equaling or exceeding a maximum count value. An improper line-to-neutral voltage can be detected by monitoring the line-to-neutral voltage and comparing it to a function such as a trip curve. Thus, components downstream from a circuit breaker, as well as the circuit breaker itself, can be protected from prolonged exposure to improper voltages, which can lead to component failure.

Abstract: An over voltage protection (OVP) monitoring system and a method thereof. The OVP monitoring system includes a battery pack connected to an external system, the battery pack including a battery, a first memory to store a voltage value of the battery, a second memory comprising a first sub-memory and a second sub-memory to store numbers of OVP operations of the battery, a controller to store the voltage value of the battery in the first memory upon an occurrence of an OVP operation and to increment a number of OVP operations stored in either the first sub-memory or the second sub-memory according to the voltage value of the battery stored in the first memory and a signal generator to generate either a first alarm signal or a second alarm signal based on the contents of the first and second sub-memories.

Abstract: Aspects of the invention provide an electrostatic discharge (ESD) protection device for eliminating current leakage, and a related method. In one embodiment, an ESD protection device includes: a resistor-capacitor (RC) circuit for receiving a power supply voltage; an ESD clamp including a plurality of n-type field-effect transistors (nFETs) for protecting the IC during an ESD event; a trigger circuit for receiving an output of the RC circuit and generating a trigger pulse to turn on the ESD clamp during the ESD event; and an nFET bias selection circuit connected to the trigger circuit, the nFET bias selection circuit for selecting one of: a low voltage supply or a negative bias voltage supply for the trigger circuit, such that the trigger circuit generates a trigger pulse, in response to selecting the negative bias voltage supply, to turn off the ESD clamp during normal operation.

Abstract: A protection circuit includes a controllable discharge element having a load path coupled between a first second circuit nodes. The discharge element provides a discharge path between the first and the second circuit nodes when in an on state. A trigger circuit has a first connection coupled to the first circuit node and a second connections coupled to the second circuit node. The trigger circuit is configured to produce a drive signal that switches the discharge element to its on state when the voltage between the first and the second circuit nodes reaches a trigger value. A setting circuit coupled to the trigger circuit is configured to change the trigger value from a first trigger value to a second trigger value depending on a voltage between the first and the second circuit nodes and/or on the drive signal.

Abstract: The application relates to a method of enabling a high voltage input and/or output in a standard IC process, the high voltage being higher than specified for I/O transistors of the IC process. The application further relates to a transceiver IC and to an article of manufacture comprising a transceiver IC. The object of the present application is to provide an integrated circuit in a standard IC process that supports larger than specified input/output swings. The problem is solved in that providing that high voltage inputs or outputs of an IC implemented in said standard IC process comprise passive impedance transformation circuitry. This has the advantage of facilitating the use of a standard IC process for higher than specified voltage I/Os. The standard IC process is preferably a CMOS or BiCMOS semiconductor process. The invention may e.g. be used for low power communication devices, e.g. portable devices having a wireless interface, e.g. listening devices, e.g. hearing instruments.

Abstract: A semiconductor device includes a first node receiving an external voltage, a second node receiving a grounding voltage, a protection circuit, and a device to be protected coupled in parallel between the first and second nodes, in which the protection circuit includes a lateral IGBT having an emitter coupled to the second node and an avalanche diode having an anode coupled to the collector of the lateral IGBT and a cathode coupled to the first node, and a clamp driving circuit coupled between the first and second nodes, and coupled to the gate of the lateral IGBT.

Abstract: A load driving device according to an exemplary aspect of the present invention includes: an output transistor coupled between a first power supply line and an output terminal; the output terminal being configured to be coupled with a load; a driver circuit that controls conduction/non-conduction of the output transistor; a compensation transistor that is coupled between the output terminal and a second power supply line, and becomes conductive when the driver circuit renders the output transistor non-conductive and when a potential of the second power supply line reaches a predetermined value or greater, to maintain a non-conduction state of the output transistor; and a first resistor coupled between the second power supply line and a back gate of the compensation transistor.

Abstract: The present invention is to provide a packaged chip having a protective component integrated with a signal isolation transformer, wherein the signal isolation transformer comprises a primary side and a secondary side, and the primary side includes an input port electrically connected to the signal input slot, and a primary side central tapped port, and the secondary side includes an output port electrically connected to the internal signal processing unit and a secondary side central tapped port. Using such structure, the chip has the functions of surge protection as well as noise treatment, and the problem that the conventional protective circuit occupying too much space is solved.

Abstract: Embodiments for at least one method and apparatus of generating a regulated voltage are disclosed. One apparatus includes a voltage regulator. The voltage regulator includes regulator circuitry for generating a regulated voltage from a first power supply and a second power supply, and voltage spike protection circuitry for voltage-spike-protecting the regulator circuitry. The voltage spike protection circuitry includes a charge-storage circuit, and at least one switching element, wherein the at least one switching element comprises a plurality of switching block segments. The charge-storage circuit includes charge-storage circuit segments, and each charge-storage circuit segment is physically closer to at least one of the plurality of switching block segments the charge-storage circuit segment protects, than any other switching block segment.

Abstract: An enhanced turn-on time SCR based electrostatic discharge (ESD) protection circuit includes an integrated JFET, method of use and design structure. The enhanced turn-on time silicon controlled rectifier (SCR) based electrostatic discharge (ESD) protection circuit includes an integrated JFET in series with an NPN base.

Abstract: The surge arrester with a replaceable overvoltage protection module in a single-pole or a multi-pole configuration, consisting of the U-shaped overvoltage protection base (5) adjusted for inserting one or three or four overvoltage protection replaceable modules (2), where the overvoltage protection replaceable module (2), featuring a visual status signaling window (17) of the thermal disconnector implemented via a visual signaling flexible strip (18), comprises C-shaped plug contacts (1) on the opposite lateral sides and a coding field (4) on one or both lateral sides, comprising of rectangular projections and/or indentations of a different profile, width and length, which slide in the complementary indentations and/or projections on one or both internal lateral sides of the overvoltage protection base (5).

Abstract: A driver circuit and a diagnostic method are provided. The driver circuit includes a first voltage driver, a second voltage driver, and a microprocessor. The microprocessor generates a first pulse width modulated signal to induce the first voltage driver to output a second pulse width modulated signal to energize a contactor coil. The microprocessor sets a first diagnostic flag equal to a first value if a first filtered voltage value is greater than a first threshold value. The microprocessor sets a second diagnostic flag equal to a second value if a second filtered voltage value is greater than a second threshold value. The microprocessor stops generating the first pulse width modulated signal to de-energize the contactor coil if the first and second diagnostic flags are set equal to the first and second values, respectively.

Abstract: An overvoltage protection method and circuit includes a positive supply input node, an output node, and a negative supply node. The overvoltage protection circuit further includes a first functional circuit configured to turn ON a MOSFET and maintain it in a low resistance state. A second functional circuit is configured to detect an overvoltage and control the gate of the MOSFET to regulate a voltage at the output node. A third functional circuit is configured to provide a startup wherein the overvoltage protection circuit is not damaged and/or to regulate an operating voltage such that an overvoltage does not appear on the overvoltage protection circuit. The external components include the MOSFET, which has a gate coupled to the output of the charge pump of the overvoltage protection circuit.

Abstract: The disclosed embodiments include a surge protection module that includes an overvoltage protection component and a ground pin configured on a bottom end of the surge protection module. The ground pin is in electrical communication with the overvoltage protection component. The surge protection module also includes a pair of outside plant tip and ring pins configured on the bottom end of the surge protection module. The pair of outside plant tip and ring pins in electrical communication with the overvoltage protection component. The surge protection module is configured to receive a wire wrap pair consisting of a central office tip wire and a central office pin wire. The central office tip wire and the central office pin wire are configured to be in electrical communication with the overvoltage protection component.

Abstract: An output circuit includes a first transistor coupled to an external terminal and having a gate terminal that receives a first drive signal. The first transistor pulls down a potential at the external terminal when activated in accordance with the first drive signal. The output circuit also includes a capacitor. The capacitor includes a first end coupled to the gate terminal of the first transistor. A clamp circuit, coupled to a second end of the capacitor, clamps the second end of the capacitor to a potential corresponding to the operation of the first transistor. The first transistor includes a drain terminal that is not coupled to the capacitor but is coupled to the external terminal.

Abstract: A hybrid switch circuit includes a hybrid switch that couples an input conductor connected to an AC power supply to an output conductor connected to a load. The hybrid switch includes a power semiconductor in parallel with an electromagnetic relay. A control circuit turns on the hybrid switch by turning on the power semiconductor at a zero-voltage crossing of the AC voltage to provide a conductive path and then closing the relay to provide a conductive bypass path that bypasses the power semiconductor. The control circuit turns off the hybrid switch by opening the relay and subsequently turning off the power semiconductor at a zero crossing of the load current. The control circuit operates in response to at least one switch control signal that indicates whether an operating fault condition exists.

Abstract: Systems and methods are disclosed for securing a programmable integrated circuit device against an over-voltage attack. Generally, programmable devices, such as FPGAs, contain volatile memory registers that may store sensitive information. To prevent tampering and/or reverse engineering of such a programmable device, an over-voltage detection circuit may be employed to disable the device and/or erase the sensitive information stored on the device when an over-voltage attack is suspected. In particular, once the over-voltage detection circuit detects that the voltage applied to the programmable device exceeds a trigger voltage, it may cause logic circuitry to erase the sensitive information stored on the device. Desirably, the over-voltage detection circuit includes components arranged in such a way as to render current consumption negligible when the voltage applied to the programmable device, e.g., by a battery, remains below the trigger voltage.

Abstract: The subject matter of the invention is a device for diverting surge currents or transient overvoltages (1), with a switching stage (2) and a switching element (3). The switching stage (2) is so designed as to switch on the switching element (3) upon identification of an overvoltage or a surge current. The switching element (3) is a reversible semiconductor switching element, while the switch-on event is achieved by operating of the switching element (3) outside of the specified parameters.

Abstract: An overvoltage protection circuit connected to protect electrical components from overvoltage conditions includes a blocking diode connected in series with a transient voltage suppression device (TVS) via a first node and includes a reference voltage for biasing the first node at a voltage sufficient to reverse bias the blocking diode during normal operations. A built-in test circuit associated with the overvoltage protection circuit includes a resistor connected to the first node and a switch connected in series with the resistor that is selectively turned On and Off. The built-in test circuit monitors voltage on a control line associated with the electrical components and at the first node while the switch is Off and while the switch is On, and detects fault conditions based on the monitored voltages.

Abstract: It is presented a protection circuit for a drive circuit of a permanent magnet motor being powered by a main DC source. The protection circuit comprises a protection circuit DC source; a changeover switch being arranged to select an input to a gate of a main drive switch of the drive circuit, the input being selectable between an output of the protection circuit DC source and a second control signal; and a changeover control device connected to control the changeover switch, which changeover control device is arranged to ensure that the changeover switch is connected to the output of the second side of the protection circuit DC source when an overvoltage is detected.

Abstract: A spark gap device includes an optional insulating layer formed on a substrate, a metal layer formed on a surface of the insulating layer, a solder resist layer formed on a surface of the metal layer, and first and second contacts. The metal layer includes a central portion and a peripheral portion separated by an air gap that surrounds the central portion of the metal layer and exposes the insulating layer. The solder resist layer includes a central portion disposed on the central portion of the metal layer having a first opening exposing a central region of the central portion of the metal layer, and a peripheral portion disposed on the peripheral portion of the metal layer having a second opening exposing a peripheral region of the peripheral portion of the metal layer. The first contact is formed in the first opening and the second contact is formed in the second opening.

Abstract: An overvoltage protection circuit and a portable electronic device having the same are introduced. The overvoltage protection circuit provides overvoltage protection when an input voltage exceeds a rated voltage tolerable by an internal circuit unit in the portable electronic device. A reference voltage and a partial voltage are generated from the input voltage through a voltage limiting unit and voltage dividing module, respectively, and conveyed to a comparing module for comparison. Comparison of the reference voltage and the partial voltage is followed by generation of a switch signal whereby a switch unit determines whether to apply the input voltage to the internal circuit unit. The voltage dividing module sets the maximum rated voltage tolerable by the internal circuit unit and enables the overvoltage protection circuit to give overvoltage protection to the portable electronic device regardless of temperature.

Abstract: A consumer electronic device including an electronic circuit designed to protect a user-actuated physical button from becoming degraded due to electrostatic discharges (ESD) strikes is described herein. The device includes a housing and the user-actuated physical button is exposed through the external surface of the housing. The device further includes a mechanical switch that is coupled to the physical button and a first resistor that is electrically coupled with a pair of terminals of the switch. The first resistor may be coupled either in series or in parallel with the terminals of the switch. To protect the first resistor from ESD strikes, a first spark gap is coupled in parallel with the first resistor. The device may also include a buffer circuit that is coupled to the switch. Other embodiments are also described.

Abstract: A surge protection circuit is disclosed for an electrical Load which may be for instance an LED load which is directly connected to a supply such as mains supply, and comprises a plurality of switches which are distributed across a plurality of semiconductor die. A surge detector detects the start of a spike in the supply, which results from, for example the commencement or interruption of a nearby inductive load, and opens all the switches. By distributing the switches across multiple die the peak voltage across each is reduced relative to using a single die; thereby each die can stay within the absolute maximum voltage capacity. Each die may have its own surge detector; alternatively, a single surge detector may be used which communicates with the switches on each of the die. In an extension the bridge rectifier may be integrated into the circuit distributed across the die. In this embodiment additional inter-die clamping diodes are required to prevent unsafe floating of the edge connections of each die.

Abstract: A test device (1) for testing power engineering equipment comprises at least one connection socket (4) which is electrically connected to an overvoltage protection arrangement (2). The overvoltage protection arrangement (2) comprises at least one overvoltage protection element (5) and is configured such that the at least one overvoltage protection element (5) is exchangeable.

Abstract: In one aspect, the present subject matter discloses a method for overvoltage protection of an electrical system. The method may generally include detecting an overvoltage condition on an electrical system; and switching on, in response to the detected overvoltage condition, an impedance connected to the electrical system, wherein the impedance clamps voltage on the electrical system.