A low dropout (ldo) regulator for generating an output voltage on an output from an input voltage of an input source. The ldo regulator including a switch module to generate the output voltage. The switch module including at least two parallel connected switches responsive to corresponding switch control signals to regulate a flow of energy from the input source to the output. Each of the switches having an on-state and an off-state. A digital controller to sense the output voltage and in response to generate the switch control signals such that the output voltage is regulated to a predetermined amplitude.
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19. A semiconductor device formed on a single semiconductor die, the semiconductor device comprising:
a digital ldo regulator for generating an output voltage on an output from a source of an input voltage; and
a digital logic device that communicates with the digital ldo regulator,
wherein the digital ldo regulator comprises:
a switch module to generate the output voltage,
wherein:
the switch module includes at least two parallel connected switches responsive to corresponding switch control signals to regulate a flow of energy from the input voltage source to the output; and
each of the at least two parallel connected switches have an on-state and an off-state; and
a digital controller to sense the output voltage and to generate the switch control signals in response to the output voltage such that the output voltage is regulated to a predetermined amplitude.
16. A multi-chip module comprising:
a first semiconductor die comprising a digital ldo regulator for generating an output voltage on an output from a source of an input voltage; and
a second semiconductor die comprising a digital logic device that communicates with the first semiconductor die,
wherein the digital ldo regulator comprises:
a switch module to generate the output voltage,
wherein:
the switch module includes at least two parallel connected switches responsive to corresponding switch control signals to regulate a flow of energy from the input voltage source to the output; and
each of the at least two parallel connected switches have an on-state and an off-state; and
a digital controller to sense the output voltage and to generate the switch control signals in response to the output voltage such that the output voltage is regulated to a predetermined amplitude.
1. A digital low dropout (ldo) regulator for generating an output voltage on an output from a source of an input voltage, the ldo comprising:
a switch module to generate the output voltage,
wherein:
the switch module includes at least two parallel connected switches responsive to corresponding switch control signals to regulate a flow of energy from the input voltage source to the output; and
each of the at least two parallel connected switches have an on-state and an off-state; and
a digital controller to sense the output voltage and to generate the switch control signals in response to the output voltage such that the output voltage is regulated to a predetermined amplitude,
wherein the at least two conduction switches, the at least two inductors, and the at least two freewheeling switches are connected in a 1:−1 configuration such that the output voltage is approximately a negative of the input voltage.
40. A digital low dropout (ldo) regulator for generating an output voltage on an output from a source of an input voltage, comprising:
a switch module to generate the output voltage,
wherein:
the switch module includes at least two parallel connected switches responsive to corresponding switch control signals to regulate a flow of energy from the input voltage source to the output; and
each of the at least two parallel connected switches have an on-state and an off-state; and
a digital controller to sense the output voltage and to generate the switch control signals in response to the output voltage such that the output voltage is regulated to a predetermined amplitude,
wherein:
the switch module is a coupled inductor regulator comprising at least a first switch pair and a second switch pair connected together through corresponding coupled inductors;
each of the first switch pair and the second switch pair includes a conduction switch array in communication with a freewheeling switch array;
the conduction switch array of the at least first switch pair including X≧1 parallel connected switches;
the conduction switch array of the at least second switch pair includes N≧1 parallel connected switches;
the freewheeling switch array of the at least first switch pair includes Y≧1 parallel connected switches; and
the freewheeling switch array of the at least second switch pair includes M≧1 parallel connected switches.
22. A digital low dropout (ldo) regulator for generating an output voltage on an output from a source of an input voltage, the ldo comprising:
means for voltage generating to generate the output voltage,
wherein:
the means for voltage generating including at least two parallel connected means for switching responsive to corresponding switch control signals to regulate a flow of energy from the input voltage source to the output; and
each of the at least two parallel connected means for switching having an on-state and an off-state; and
means for digital controlling to sense the output voltage and to generate the switch control signals in response to the output such that the output voltage is regulated to a predetermined amplitude,
wherein:
the means for voltage generating includes a coupled inductor regulator;
the at least two parallel connected means for switching are a conduction switch array that is responsive to the switch control signals to generate the output voltage;
each of the switch control signals have a duty cycle of approximately 50%; and
the coupled inductor regulator comprises:
at least two means for conduction switching to conduct energy from the source of the input voltage to the output;
at least two inductors in communication with the at least two means for conduction switching,
wherein:
the at least two inductors are wound together on a common core;
each of the at least two inductors has a polarity such that DC currents in the inductors cancel each other; and
the at least two inductors have coefficient of coupling approximately equal to one; and
at least two means for freewheeling switching in communication with the at least two means for conduction switching to provide a path for current during non-conduction periods;
the switch control signals each have a duty cycle of approximately 50% and are used to control the at least two means for conduction switching;
each of the at least two means for conduction switching comprises a conduction switch array;
the at least two means for conduction switching, the at least two inductors, and the at least two means for freewheeling switching are connected in a boost configuration such that the output voltage is approximately twice the amplitude of the input voltage; and
the boost configuration includes two boost regulators each operating at approximately 50% duty cycle, each boost regulator including; and
a means for conduction switching in communication with a means for freewheeling switching and an inductor,
wherein:
the means for conduction switching to provide current during a conduction period from the a high side of the source of the input voltage through the inductor to a low side of the source of the input voltage; and
the means for freewheeling switching to provide a conduction path during the non-conduction period for current flowing from the high side of the source of the input voltage through the inductor to the output.
2. The digital ldo regulator of
the switch module is a coupled inductor regulator;
the at least two parallel connected switches are a conduction switch array that is responsive to the switch control signals to generate the output voltage; and
each of the switch control signals have a duty cycle of approximately 50%.
3. The digital ldo regulator of
the switch module is a digital resistor; and
the at least two parallel connected switches are a switch array.
4. The digital ldo regulator of
an analog-to-digital converter to generate a digital signal of the output voltage; and
a digital circuit, responsive to the digital signal, to generate the switch control signals.
5. The digital ldo regulator of
6. The digital ldo regulator of
the digital circuit includes a burst mode to operate the switch module at low output current; and
the burst mode including duty cycle control of the at least two parallel connected switches to regulate the output voltage.
7. The digital ldo regulator of
a group of parallel switches responsive to a first one of the switch control signals; and
a single switch responsive to a second one of the switch control signals.
8. The digital ldo regulator of
at least two conduction switches to conduct energy from the source of the input voltage to the output;
at least two inductors in communication with the at least two conduction switches,
wherein:
the at least two inductors are wound together on a common core and each inductor has a polarity such that DC currents in the at least two inductors cancel each other; and
the inductors have a coefficient of coupling that is approximately equal to one; and
at least two freewheeling switches in communication with the at least two conduction switches to provide a path for current during non-conduction periods
wherein:
the switch control signals each have a duty cycle of approximately 50% and are used to control the at least two conduction switches; and
each of the at least two conduction switches comprises a conduction switch array.
9. The digital ldo regulator of
10. The digital ldo regulator of
11. The digital ldo regulator of
the buck configuration includes two buck regulators each operating at approximately 50% duty cycle;
each buck regulator includes a conduction switch that is in communication with a freewheeling switch and an inductor;
the conduction switch is configured to provide current during a conduction period from the source of input voltage through the inductor to the output; and
the freewheeling switch is configured to provide a conduction path during the non-conduction period for current flowing through the inductor to the output.
12. The digital ldo regulator of
13. The digital ldo regulator of
the boost configuration includes two boost regulators each operating at approximately 50% duty cycle;
each boost regulator includes a conduction switch that is in communication with a freewheeling switch and an inductor;
the conduction switch configured to provide current during a conduction period from the a high side of the source of the input voltage through the inductor to a low side of the source of input voltage; and
the freewheeling switch to provide a conduction path during the non-conduction period for current flowing from the high side of the source of the input voltage through the inductor to the output.
14. The digital ldo regulator of
15. The digital ldo regulator of
the 1:−1 configuration includes two flyback regulators each operating at approximately 50% duty cycle;
each flyback regulator includes a conduction switch that is in communication with a freewheeling switch and an inductor;
the conduction switch is configured to provide current during a conduction period from the a high side of the source of the input voltage through the inductor to a low side of the source of the input voltage; and
the freewheeling switch is configured to provide a conduction path during the non-conduction period for current flowing from the output through the inductor to the low side of the source of the input voltage.
17. The multi-chip module of
20. The semiconductor device of
23. The digital ldo regulator of
the means for voltage generating is a digital resistor; and
the at least two parallel connected means for switching are a switch array.
24. The digital ldo regulator of
means for analog-to-digital converting to generate a digital signal of the output voltage; and
means for generating switch control signals, responsive to the digital signal, to generate the switch control signals.
25. The digital ldo regulator of
26. The digital ldo regulator of
the means for generating switch control signals includes a burst mode to operate the switch module at low output current; and
the burst mode includes duty cycle control of the at least two parallel connected means for switching to regulate the output voltage.
27. The digital ldo regulator of
a group of parallel switches responsive to a first one of the switch control signals; and
a single switch responsive to a second one of the switch control signals.
28. The digital ldo regulator of
29. The digital ldo regulator of
30. The digital ldo regulator of
the buck configuration includes two buck regulators each operating at approximately 50% duty cycle;
each buck regulator includes a means for conduction switching in communication with a means for freewheeling switching and an inductor;
the means for conduction switching configured to provide current during a conduction period from the source of the input voltage through the inductor to the output; and
the means for freewheeling switching to provide a conduction path during the non-conduction period for current flowing through the inductor to the output.
31. The digital ldo regulator of
32. The digital ldo regulator of
the 1:−1 configuration includes two flyback regulators each operating at approximately 50% duty cycle;
each flyback regulator includes a means for conduction switching in communication with a means for freewheeling switching and an inductor;
the means for conduction switching configured to provide current during a conduction period from the a high side of the source of the input voltage through the inductor to a low side of the source of the input voltage; and
the means for freewheeling switching to provide a conduction path during the non-conduction period for current flowing from the output through the inductor to the low side of the source of the input voltage.
33. A multi-chip module comprising:
a first semiconductor die comprising the digital ldo regulator of
a second semiconductor die comprising means for performing digital logic operations.
34. The multi-chip module of
35. The multi-chip module of
36. A semiconductor device formed on a single semiconductor die, the semiconductor device comprising:
the digital ldo regulator of
means for performing digital logic operations.
37. The semiconductor device of
38. The semiconductor device of
39. The digital ldo regulator of
the switch module is a coupled inductor regulator;
the at least two parallel connected switches are at least one of a conduction switch array and a freewheeling switch array;
the at least two parallel connected switches are responsive to the switch control signals to generate the output voltage; and
each of the switch control signals have a duty cycle of approximately 50%.
41. The digital ldo regulator of 22, wherein:
the means for voltage generating is a coupled inductor regulator;
the at least two parallel connected means for switching are at least one of a conduction switch array and a freewheeling switch array;
the at least two parallel connected means is responsive to the switch control signals to generate the output voltage; and
each of the switch control signals have a duty cycle of approximately 50%.
42. The digital ldo regulator of
the means for voltage generating is a coupled inductor regulator comprising at least a first switch pair and a second switch pair connected together through corresponding coupled inductors;
each of the first switch pair and the second switch pair includes a conduction switch array in communication with a freewheeling switch array;
the conduction switch array of the at least first switch pair includes X≧1 parallel connected means for switching;
the conduction switch array of the at least second switch pair includes N≧1 parallel connected means for switching;
the freewheeling switch array of the at least first switch pair includes Y≧1 parallel connected means for switching; and
the freewheeling switch array of the at least second switch pair includes M≧1 parallel connected means for switching.
43. The digital ldo regulator of
a first conduction time of one of the conduction switches is separated from a second conduction time of another of the conduction switches by non-conduction time; and
a duration of the non-conduction time is substantially less than a duration of both the first conduction time and the second conduction time.
44. The digital ldo regulator of
45. The digital ldo regulator of
the at least two conduction switches include a first conduction switch that receives a first drive signal and a second conduction switch that receives a second drive signal;
the at least two freewheeling switches include a first freewheeling switch that receives the second drive signal and a second freewheeling switch that receives the first drive signal; and
the first and second drive signals are the same signal with a phase offset that is equal to 360 degrees divided by a total number of the conduction switches.
46. The digital ldo regulator of
a first conduction time of one of the at least two means for conduction switching is separated from a second conduction time of another of the at least two means for conduction switching by non-conduction time; and
a duration of the non-conduction time is substantially less than a duration of both the first conduction time and the second conduction time.
47. The digital ldo regulator of
48. The digital ldo regulator of
one of the at least two means for conduction switching receives a first drive signal;
another of the at least two means for conduction switching receives a second drive signal;
one of the at least two means for freewheeling switching receives the second drive signal;
another of the at least two means for freewheeling switching receives the first drive signal; and
the first and second drive signals are the same signal with a phase offset that is equal to 360 degrees divided by a total number of the conduction switches.
49. The digital ldo regulator of
51. The digital ldo regulator of
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This application is a continuation-in-part of U.S. non-provisional application Ser. No. 10/693,787, filed Oct. 24, 2003, which claims the benefit of the filing date of U.S. provisional application No. 60/496,957 filed Aug. 21, 2003, the entire contents of which are herein incorporated by reference.
An aspect of this invention relates to power systems for electronic circuits.
Low dropout voltage regulators are widely used to provide voltage regulation in electronics sub-systems. An LDO may be most effectively used when the difference voltage between the input supply voltage and the regulated output voltage is very small. The smaller the difference voltage is, the higher the power efficiency of the LDO. For example, the efficiency of a 2.5 volt LDO operating from a 3.3 volt supply is about 75%. Although, the efficiency of an LDO is relatively poor in comparison to a conventional high performance DC/DC converter, it may be offset by the relatively low cost of the LDO. However, as the difference voltage across the LDO increases, the efficiency of the LDO may become prohibitively low. For example, when generating a 1.2 volt regulated supply voltage from a 3.3 volt supply the efficiency of an LDO decreases to a very poor 36%. Unfortunately, present day digital integrated circuits operate with a supply voltage of approximately 1.2 volts or less, while the lowest output voltage from a typical DC/DC converter is approximately 3.3 volts, leading to excessive losses in conventional LDO regulators.
A low dropout (LDO) regulator for generating an output voltage on an output from an input voltage of an input source. The LDO regulator including a switch module to generate the output voltage. The switch module including at least two parallel connected switches responsive to corresponding switch control signals to regulate a flow of energy from the input source to the output. Each of the switches having an on-state and an off-state. A digital controller to sense the output voltage and in response to generate the switch control signals such that the output voltage is regulated to a predetermined amplitude.
The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.
Like reference symbols in the various drawings indicate like elements.
The coupled-inductor regulator 10 may include conduction switches 11, freewheeling switches 12, and two or more coupled inductors 13 arranged in a buck, a flyback, or a boost configuration. A drive signal generator 14 may generate drive signals to control the conduction switches 11. The drive signals are controlled to generate a total conduction time approaching 100%, negating a small amount of deadtime to reduce cross-conduction between the conduction switches 11 and the freewheeling switches 12.
A frequency generator 15 may generate a clock signal having an operating frequency. The drive signals may be synchronized to operate at the operating frequency. In one aspect, the operating frequency may be fixed to a predetermined frequency. In another aspect, the operating frequency may be controlled in response to changes in load conditions such as output current and output voltage. For example, when a change in the output current, such as an increase in load current, is sensed, the operating frequency may be increased to increase the transient response of the output. Once the coupled inductor regulator 10 has responded to the change in load condition and has reached steady-state operating conditions again, the operating frequency may be decreased to reduce power losses in the coupled inductor regulator 10.
The coupled inductors 13 may be tightly coupled together preferably having a coefficient of coupling, K, of approximately one, where unity is the ideal value. Preferably the inductors 13 are wound together on a common magnetic core to form an inductor assembly that provides the maximum value of coefficient of coupling. The coefficient of coupling is approximately one being at least 0.9 and preferably greater than 0.99. The polarity for each of the windings for the coupled inductors 13 are selected so that DC currents flowing through the coupled inductors 13 approximately cancel, leading to approximately zero DC current flowing through the magnetic core of the inductor assembly. Since there is virtually no DC current flowing through the inductor assembly, a smaller core size may be used for the coupled inductors resulting in a smaller size (volume) and lower cost for the inductor assembly. In addition, high permeability core materials may be used for the magnetic core such as ferrites having shapes such as bead and toroid. Lower permeability materials may also be used such as MPP cores, ferrite PQ cores, and other split core shapes.
In addition to the steady-state advantages obtained by maximizing the coefficient of coupling between the coupled inductors, the transient response of the coupled inductor regulator 10 may also be improved. During a transient, the high mutual coupling between the coupled inductors may effectively cancel the inductance of the individual inductors as far as the transient load current is concerned.
The conduction switches 11 may also be driven using a multi-level gate voltage to reduce switching losses. For example, the amplitude of the on voltage may be adjusted to differing predetermined levels dependent on factors such as the current flowing through the conduction switch to decrease switching losses in the conduction switch.
The inductors, 26a and 26b, may be tightly coupled together preferably having a coefficient of coupling, K, of approximately one, where unity is the ideal value. Preferably the inductors 26a and 26b are wound together on a common magnetic core to form an inductor assembly 27 that provides a high value of coefficient of coupling between the inductors 26a and 26b. The polarities of the inductor windings are selected so that the DC currents flowing through the inductors 26a and 26b approximately cancel so that approximately zero DC current flows through the magnetic core of the inductor assembly 27. Therefore, a smaller core size with a low permeability material may be used for the inductors 26a and 26b, resulting in a smaller size (volume) and lower cost for the inductor assembly 27. In addition, the transient response of the 2:1 buck regulator 20 is improved due to cancellation of the individual inductances as far as transient load currents are concerned.
Any type of switches may be used for the free-wheeling switches 24a and 25b such as synchronous rectifiers and discrete rectifiers.
Using a two level gate voltage for the conduction switches 22a and 22b is particularly advantageous with the 2:1 buck converter 20 since the output voltage, VDD/2, may be used as the intermediate level voltage for driving the conduction switches.
Each of the conduction switches 52a and 52b are controlled by drive signals that are operated approximately 180 degrees out-of-phase. The first conduction switch 52a may be driven by a signal Φ1 that is approximately a square-wave. The second conduction switch 52b may be driven a second signal
The inductors, 56a and 56b, for each of the boost converters may be tightly coupled together preferably having a coefficient of coupling, K, of approximately one. The inductors 56a and 56b may be wound together on a single magnetic core to form an inductor assembly 57 that provides a high value of coefficient of coupling. The benefits of having a high coefficient of coupling are similar to those of the 2:1 regulator 20 and the coupled inductor regulator 10.
Any type of switches may be used for the free-wheeling switches 54a and 55b such as synchronous rectifiers and discrete rectifiers.
Pairs of the coupled inductors 156a-156b, 156c-156d, and 156e-156f may each be tightly coupled together preferably having a coefficient of coupling, K, of approximately one. Preferably each pairs of inductor 156a-156b, 156c-156d, and 156e-156f is wound together on a corresponding common magnetic core to form inductor assemblies that may provide a high value of coefficient of coupling between the inductors 156a-156b, 156c-156d, and 156e-156f. The polarities of the inductor windings are selected so that the DC currents flowing through each pair of inductors 156a-156b, 156c-156d, and 156e-156f approximately cancel so that approximately zero DC current flows through the magnetic core of the corresponding inductor assembly. In another aspect, all of the inductors 156a-156f may be wound on a single magnetic core.
The drivers 152a-152d may advantageously be included on a single semiconductor die to reduce cost, or decrease the volume of the 4:1 regulator. The phase signals each may have an on-state and an off-state, and a duty cycle of approximately 25%. The phase signals may be arranged in a timing sequence such as in one aspect, an alternating timing sequence, PS1, and in another aspect the phase signals may be arranged in a sequential timing sequence, PS2. In the alternating timing sequence PS1, phase signals φ1-φ3-φ2-φ4 respectively are applied to the drivers 152a-152b-152c-152d (see
Signal PS1-A shows the waveform at node A of
Pairs of the coupled inductors 167 within each stage may be tightly coupled together preferably having a coefficient of coupling, K, of approximately one. Preferably each pair of inductors 167 is wound together on a corresponding common magnetic core to form inductor assemblies that may provide a high value of coefficient of coupling between the inductors 166. For example, stage two may have two inductor assemblies and stage three may have four inductor assemblies. The polarities of the inductor windings are selected so that the DC currents flowing through each pair of inductors 167 approximately cancel so that approximately zero DC current flows through the magnetic core of the corresponding inductor assembly. In another aspect, all of the inductors 166 may be wound on a single magnetic core.
In addition, the overall power efficiency of the VLVHC regulator 320 may be lower than if only a non-isolated buck converter were used to convert Vin to Vout.
In one aspect, a 2:1 regulator 406 may generate a voltage, Vo2, that is approximately one-half of the amplitude of VDD. The voltage, Vo2, may be applied to one end of the load 402 to bias the load 402 so that no DC voltage appears across the load 402, thereby eliminating the need for a DC blocking capacitor. In one aspect the 2:1 regulator 406 and the power amplifier 404 may be fabricated on a single integrated circuit 401.
In another aspect, a 1:−2 regulator 408 may generate a voltage, −VDD, that is the negative of the high side supply voltage, VDD, for the power amplifier 404. The voltage −VDD is used as the low side supply voltage for the power amplifier 404 to convert the power amplifier 404 into a dual power supply amplifier. The power amplifier 404 may then generate generates an output that is approximately centered about zero volts and has approximately no DC component, thereby eliminating the need for a DC blocking capacitor. In one aspect the 1:−1 regulator 408 and the power amplifier 404 may be fabricated on a single integrated circuit 411.
Any combination of switch arrays may be used in the coupled inductor regulator 1002 so long as at least one conduction switch or freewheeling switch is replaced by a switch array. For example, the buck configuration coupled inductor regulators 1020, 1040, and 1060 shown in
Referring to
In one exemplary digital LDO regulator having an input voltage of 3.3 volts, the coupled inductor regulator 1002 may be a buck configuration so that the output voltage would be approximately equal to 1.65 volts (one-half of the input voltage) if the coupled inductor regulator 1002 were operated open-loop. However, with the digital controller 1004 controlling the conduction switch array 1006, the output voltage may be regulated at voltages approximately equal to or less than 1.65 volts.
In another aspect, the digital circuit 1012 may include a burst mode 1012 for controlling the duty cycle of the switches of the conduction switch array 1006. Burst mode 1012 may advantageously provide improved regulation during operation at low output current, Iout, levels such as when Iout is so low that controlling the quantity of conducting switches is not sufficient to regulate the output voltage. The burst mode may be operated in combination with controlling the quantity of conducting switches in the conduction switch array 1006.
The digital LDO regulator 1106 may include a coupled inductor regulator 1108 and digital controller 1110 as described earlier in this specification. The digital controller 1106 may include a control loop, 1112a and 1112b, to control the output voltage of the DC/DC converter 1104 so that the input voltage of the coupled inductor regulator 1108 is minimized, thereby limiting the power dissipation and increasing the maximum output current that the digital LDO regulator 1108 may supply without dropping out of regulation during a transient load change. The control loops of the digital controller 1110 may be configured so that the control loop of the coupled inductor regulator 1108 is a fast loop 1112a while the control loop of the DC/DC converter 1104 is a slow loop 1112b. Since the DC/DC converter 1104 does not require a fast response time, the DC/DC converter 1104 may advantageously be operated at a lower operating frequency leading to higher power efficiency. The conduction losses are decreased and the efficiency of the DC/DC converter 1004 is further increased since the output current of the DC/DC converter 1004 is less than one-half of the output current of a DC/DC converter used in a conventional power system. Additionally, the power system does not require voltage positioning of the output voltage. Conventional DC/DC converters that supply power to a CPU typically include voltage positioning to reduce the voltage stress applied to the CPU during transient load currents. Voltage positioning is a technique wherein the amplitude of the output voltage is programmed to vary as a function of the amplitude of the output current.
A number of embodiments of the invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention. Accordingly, other embodiments are within the scope of the following claims.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
3529233, | |||
3579214, | |||
3851375, | |||
4020439, | Feb 09 1974 | U.S. Philips Corporation | Inductive stabilizing ballast for a gas and/or vapor discharge lamp |
4040174, | Jul 31 1975 | Olympus Optical Co., Ltd. | Method of manufacturing magnetic heads |
4203081, | Mar 31 1977 | Siemens Nixdorf Informationssysteme AG | Passive circuit element for influencing pulses |
4214198, | Sep 01 1977 | Dynamote Corporation | Electrical power unit |
4245286, | May 21 1979 | The United States of America as represented by the Administrator of the | Buck/boost regulator |
4273051, | Jan 17 1979 | Imperial Chemical Industries Limited | Electric device |
4384321, | Apr 29 1980 | California Institute of Technology | Unity power factor switching regulator |
4475143, | Jan 10 1983 | Circuit Components, Incorporated | Decoupling capacitor and method of manufacture thereof |
4527032, | Nov 08 1982 | ARMCO INC , A CORP OF OHIO | Radio frequency induction heating device |
4536733, | Sep 30 1982 | Sperry Corporation | High frequency inverter transformer for power supplies |
4578664, | Jun 02 1982 | Siemens Aktiengesellschaft | Radio interference suppression choke with a low leakage field |
4583068, | Aug 13 1984 | AT&T Bell Laboratories | Low profile magnetic structure in which one winding acts as support for second winding |
4616142, | Dec 31 1984 | Sundstrand Corporation | Method of operating parallel-connected semiconductor switch elements |
4675629, | Feb 18 1985 | Murata Manufacturing Co., Ltd. | Noise filter |
4801912, | Jun 07 1985 | American Precision Industries Inc. | Surface mountable electronic device |
4803609, | Oct 31 1985 | International Business Machines Corporation | D. C. to D. C. converter |
4897773, | May 03 1989 | Lincoln Global, Inc | Inverter output circuit |
5006782, | Jun 15 1989 | International Rectifier Corporation | Cascaded buck converter circuit with reduced power loss |
5079498, | Mar 26 1991 | EATON LIMITED | Digital pulse-width-modulation generator for current control |
5186647, | Feb 24 1992 | COMMSCOPE, INC OF NORTH CAROLINA | High frequency electrical connector |
5204809, | Apr 03 1992 | International Business Machines Corporation | H-driver DC-to-DC converter utilizing mutual inductance |
5303115, | Jan 27 1992 | Littelfuse, Inc | PTC circuit protection device comprising mechanical stress riser |
5363035, | Feb 26 1991 | Illinois Tool Works Inc | Phase controlled transformer |
5402329, | Dec 09 1992 | Technical Witts, Inc | Zero voltage switching pulse width modulated power converters |
5442317, | Nov 10 1992 | MOTOROLA SOLUTIONS, INC | Switching regulator and amplifier system |
5444600, | Dec 03 1992 | Analog Devices International Unlimited Company | Lead frame capacitor and capacitively-coupled isolator circuit using the same |
5475296, | Apr 15 1994 | ADEPT POWER SYSTEMS, INC 801 EL CAMINO REAL #268 | Digitally controlled switchmode power supply |
5481238, | Apr 19 1994 | DAVIDSON, CHRISTOPHER DONOVAN, MR | Compound inductors for use in switching regulators |
5500629, | Sep 10 1993 | MEYER, BARBARA L | Noise suppressor |
5509691, | Oct 26 1992 | GAO Gesellschaft fur Automation und Organisation mbH | Security element in the form of threads or strips to be embedded in security documents and a method for producing and testing the same |
5636107, | Nov 15 1995 | BEL POWER SOLUTIONS INC | DC-DC converters |
5654881, | Mar 01 1996 | BAE SYSTEMS CONTROLS INC | Extended range DC-DC power converter circuit |
5802709, | Aug 15 1995 | Bourns, Multifuse (Hong Kong), Ltd. | Method for manufacturing surface mount conductive polymer devices |
5808537, | Sep 16 1996 | Kabushiki Kaisha Toyoda Jidoshokki Seisakusho | Inductor core for transferring electric power to a conveyor carriage |
5821832, | Nov 30 1995 | SGS-Thomson Microelectronics S.A. | Signal transmission circuit |
5889373, | Dec 30 1996 | General Electric Company | Fluorescent lamp ballast with current feedback using a dual-function magnetic device |
5999417, | Jan 24 1997 | SYNQOR INC | High efficiency power converter |
6023154, | Oct 28 1997 | Infineon Technologies Americas Corp | Parallel and interwoven buck converter for high efficiency, low voltage power supply |
6043634, | Dec 22 1998 | Intel Corporation | Interleaved switching regulator |
6049264, | Dec 09 1997 | Siemens Automotive Corporation | Electromagnetic actuator with composite core assembly |
6054764, | Dec 20 1996 | Texas Instruments Incorporated | Integrated circuit with tightly coupled passive components |
6057665, | Sep 18 1998 | FIRE WIND & RAIN TECHNOLOGIES LLC, AN ARIZONA LIMITED LIABILITY COMPANY | Battery charger with maximum power tracking |
6084790, | Jan 07 1999 | Astec International Limited | Circuit to ensure equal current sharing and switching losses between parallel power devices |
6137389, | Sep 12 1995 | TDK Corporation | Inductor element for noise suppression |
6144269, | Jun 10 1997 | FUJI ELECTRIC CO , LTD | Noise-cut LC filter for power converter with overlapping aligned coil patterns |
6150798, | Sep 18 1997 | STMICROELECTRONICS S A | Voltage regulator |
6166527, | Mar 27 2000 | Analog Devices International Unlimited Company | Control circuit and method for maintaining high efficiency in a buck-boost switching regulator |
6184666, | Mar 09 1998 | RPX Corporation | Buck converter with parallel switches |
6191673, | May 21 1998 | Mitsubishi Denki Kabushiki Kaisha | Current transformer |
6229289, | Feb 25 2000 | Cadence Design Systems, INC | Power converter mode transitioning method and apparatus |
6246592, | Aug 10 1999 | Texas Instruments | Unique power supply architecture with cascaded converters for large input-to-output step-down ratio |
6255804, | Sep 18 1998 | Fire Wind & Rain Technologies LLC | Method for charging a battery with maximum power tracking |
6259235, | Aug 26 1999 | Tyco Electronics Logistics AG | Active clamp for power converter and method of operation thereof |
6282103, | Dec 28 1999 | Yokogawa Electric Corporation | Switching power supply using an inductor device to prevent harmonic current generation |
6310534, | Oct 14 1997 | Vacuumschmelze GmbH | Radio interference suppression choke |
6329801, | Apr 24 2000 | Volterra Semiconductor Corporation | Switching regulator control system and method |
6348744, | Apr 14 1998 | WASHINGTON SUB, INC ; ALPHA INDUSTRIES, INC ; Skyworks Solutions, Inc | Integrated power management module |
6356179, | Jun 03 1999 | SUMIDA CORPORATION | Inductance device |
6356462, | Aug 31 2000 | Delta Electronics, Inc. | Soft-switched full-bridge converters |
6362986, | Mar 22 2001 | Volterra Semiconductor LLC | Voltage converter with coupled inductive windings, and associated methods |
6404175, | Nov 15 1999 | Semtech Corporation | Multi-phase and multi-module power supplies with balanced current between phases and modules |
6459349, | Mar 06 2000 | ABB Schweiz AG | Circuit breaker comprising a current transformer with a partial air gap |
6483623, | Nov 28 1997 | Dowa Mining Co., Ltd. | Lamp apparatus for use in optical communication and a process for producing the same |
6493242, | Oct 01 1999 | FLEXTRONICS AUTOMOTIVE USA, INC | Power factor controller |
6512352, | Jun 07 2001 | KONINLIJKE PHILIPS ELECTRONICS N V | Active clamp step-down converter with power switch voltage clamping function |
6512437, | Jul 03 1997 | The Furukawa Electric Co., Ltd. | Isolation transformer |
6683522, | Feb 24 1999 | Milli Sensor Systems & Actuators, Inc. | Planar miniature inductors and transformers |
6686823, | Apr 29 2002 | Murata Machinery, Ltd | Inductive power transmission and distribution apparatus using a coaxial transformer |
6703815, | May 20 2002 | Texas Instruments Incorporated | Low drop-out regulator having current feedback amplifier and composite feedback loop |
6738274, | Sep 09 2002 | Hewlett Packard Enterprise Development LP | Power supply with integrated bridge and boost circuit |
6798177, | Oct 15 2002 | California Micro Devices Corporation; Analog Devices, Inc | Boost-buck cascade converter for pulsating loads |
6820321, | Sep 22 2000 | M-FLEX MULTI-FINELINE ELECTRONIX, INC | Method of making electronic transformer/inductor devices |
6822427, | May 01 2002 | Technical Witts, Inc.; Technical Witts, Inc | Circuits and circuit elements for high efficiency power conversion |
6853568, | May 20 2003 | Delta Electronics, Inc. | Isolated voltage regulator with one core structure |
6853588, | Oct 31 2002 | Electronics and Telecommunications Research Institute | First-in first-out memory circuit and method for executing same |
6967553, | Sep 20 2000 | DELTA ENERGY SYSTEMS SWITZERLAND AG | Planar inductive element |
6995685, | Sep 25 2001 | Landis+Gyr LLC | Utility meter power arrangements and methods |
20010052837, | |||
20020039061, | |||
20020118000, | |||
20020136029, | |||
20030111985, | |||
20030227366, | |||
20060116623, | |||
DE19837639, | |||
DE3622190, | |||
EP484074, | |||
EP503715, | |||
EP53715, | |||
EP632571, | |||
EP895257, | |||
EP929143, | |||
EP1239574, | |||
GB2318691, | |||
JP11008123, | |||
JP11074125, | |||
JP11146638, | |||
JP11204354, | |||
JP20020570039, | |||
JP2002095166, | |||
JP2003332141, | |||
JP2005252783, | |||
JP2008274582, | |||
JP2125404, | |||
JP2251107, | |||
JP57193007, | |||
JP58224420, | |||
JP61078111, | |||
JP6260869, | |||
RE37738, | Oct 09 1996 | ABB POWER ELECTRONICS INC | Simple and efficient switching regulator for fast transient loads such as microprocessors |
WO74089, | |||
WO143276, | |||
WO2095775, | |||
WO217469, |
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