Patent Application
20160013730
This application claims priority under 35 U.S.C. §119 to Korean Patent Application No. 10-2014-0088464, filed on Jul. 14, 2014 in the Korean Intellectual Property Office, the disclosure of which is incorporated by reference herein in its entirety.
1. Technical Field
The present inventive concept relates to a rectifier circuit for converting an alternating current (AC) voltage into a rectified voltage.
2. Discussion of Related Art
Portable devices may include a rectifier circuit to obtain a direct current (DC) voltage from an alternating current (AC) voltage. A DC voltage obtained by a rectifier circuit may be used to generate a DC current which is, for instance, used to charge a battery. Charging a battery may be performed in a wireless manner. To increase the power transfer distance in wireless charging, a rectifier circuit is required to have high conversion efficiency from an AC voltage to a DC voltage.
According to an exemplary embodiment of the present inventive concept, a rectifier circuit includes a low side switching circuit, a high side switching circuit and a low side driver. The low side switching circuit is connected between a reference node and first and second input nodes. The first and second input nodes receive an alternating current (AC) voltage. The high side switching circuit is connected between an output node and the first and second input nodes. The output node outputs a rectified voltage of the AC voltage. The low side driver is coupled to the low side switching circuit. The low side driver controls, in response to a control signal, the low side switching circuit so that the low side driving voltage and a voltage provided from one of the first and second input nodes are synchronized in phase.
According to an exemplary embodiment of the present inventive concept, a rectifier circuit includes a low side switching circuit, a high side switching circuit, first and second low side drivers, a bootstrap circuit and a high side driver. The low side switching circuit is connected between a reference node and first and second input nodes. The first and second input nodes receive an alternating current (AC) voltage. The high side switching circuit is connected between an output node and the first and second input nodes. The output node outputs a rectified voltage of the AC voltage. The first and second low side drivers are each coupled to the low side switching circuit. The first and second low side drivers are configured to generate low side driving voltages. The first and second low side drivers controls, in response to a control signal, the low side switching circuit so that the low side driving voltages provided from the first and second low side drivers are synchronized with voltages provided from the second and first input nodes, respectively. The bootstrap circuit is coupled to the second input node. The bootstrap circuit is configured to generate a bootstrapping voltage based on a bootstrap driving voltage and the voltage provided from the second input node. The high side driver is coupled to the high side switching circuit. The high side driver provides a high side driving voltage to the high side switching circuit to control the high side switching circuit and generate the high side driving voltage based on at least one of the rectified voltage, the voltages provided from the first and second input nodes, the low side driving voltage generated by the second low side driver, the bootstrap driving voltage, and the bootstrapping voltage.
According to an exemplary embodiment of the present inventive concept, a rectifier circuit is provided. A low side switching circuit is coupled between a reference node and first and second input nodes. The first and second input nodes receive an alternating current (AC) voltage. A high side switching circuit is coupled between an output node and the first and second input nodes. The output node outputs a rectified voltage of the AC voltage. First and second low side drivers are each coupled to the low side switching circuit. The first and second low side drivers generate low side driving voltages. The first and second low side drivers control, in response to a control signal, the low side switching circuit so that the low side driving voltages provided from the first and second low side drivers are synchronized with voltages provided from the second and first input nodes, respectively. A bootstrap driving voltage generator generates a bootstrap driving voltage based on the rectified voltage, the control signal, and an offset voltage. A bootstrap circuit is coupled to the high side switching circuit. The bootstrap circuit generates a bootstrapping voltage based on the low side driving voltage generated by the first low side driver and the bootstrap driving voltage and provides the bootstrapping voltage to the high side switching circuit.
According to an exemplary embodiment of the present inventive concept, a rectifier circuit is provided. First and second input nodes receive an alternating current (AC) voltage. An output node outputs a rectified voltage of the AC voltage. The rectified voltage is represented as a voltage with reference to a reference voltage. A first diode is coupled between the first input node and a reference node. The reference node has the reference voltage. A second diode is coupled between the first diode and the output node. A third diode is coupled between the second input node and the reference node. A fourth diode is coupled between the third diode and the output node. A first transistor is coupled between the first input node and the reference node. A gate terminal of the first transistor is coupled to the second input node. A second transistor is coupled between the second input node and the reference node. A gate terminal of the second transistor is coupled to the first input node.
These and other features of the inventive concept will become more apparent by describing in detail exemplary embodiments thereof with reference to the accompanying drawings of which:
Exemplary embodiments of the inventive concept will be described below in detail with reference to the accompanying drawings. However, the inventive concept may be embodied in different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, the thickness of layers and regions may be exaggerated for clarity. It will also be understood that when an element is referred to as being “on” another element or substrate, it may be directly on the other element or substrate, or intervening layers may also be present. It will also be understood that when an element is referred to as being “coupled to” or “connected to” another element, it may be directly coupled to or connected to the other element, or intervening elements may also be present. Like reference numerals may refer to the like elements throughout the specification and drawings.
Input currents Iplus and Iminus are generated based on the AC voltage Vac, and are provided to input nodes Nin1 and Nin2, respectively, of the rectifier circuit 100. For example, the input current Iplus is provided to the input node Nin1 for a half period of the AC voltage Vac, and thus, the input node Nin I has a voltage Vplus for the half period of the AC voltage Vac. For the other half period of the AC voltage Vac, the input current Iminus is provided to the input node Nin2 so that the input node Nin2 has a voltage Vminus for the other half period of the AC voltage Vac. A phase difference between the voltage Vplus of the input node Nin1 and the voltage Vminus of the input node Nin2 is 180°. Descriptions of waveforms of the voltages Vplus and Vminus of the input nodes Nin1 and Nin2 will be mentioned with reference to
The low side switching circuit 120 is connected between a reference node Nref and the input nodes Nin1 and Nin2. The reference node Nref is grounded, but the present inventive concept is not limited thereto. The low side switching circuit 120 includes switching transistors T11 and T12 and diodes D1 and D2. The transistor T11 and the diode D1 are connected in parallel between the reference node Nref and the input node Nin1, and the transistor T12 and the diode D2 are connected in parallel between the reference node Nref and the input node Nin2.
The high side switching circuit 130 be connected between the input nodes Nin1 and Nin2 and an output node Nout. As an example embodiment, the high side switching circuit 130 include diodes D3 and D4. In this example embodiment, an anode of the diode D3 be connected to the input node Nin1 and a cathode of the diode D3 be connected to the output node Nout. Further, an anode of the diode D4 be connected to the input node Nin2 and a cathode of the diode D4 be connected to the output node Nout.
The AC voltage Vac is converted into the rectified voltage Vrect by the diodes D1 and D2 and the switching transistors T11 and T12, which are included in the low side switching circuit 120, and the diodes D3 and D4, which are included in the high side switching circuit 130. The rectified voltage Vrect is outputted from the output node Nout. The low side switching circuit 120 is controlled by the low side drivers 143 and 144.
The low side driver 143 receives the voltage Vminus of the input node Nin2, and outputs a low side driving voltage Vc11. The low side driving voltage Vc11 and the voltage Vminus are synchronized in phase. The low side driving voltage Vc11 is provided to the low side switching circuit 120. The low side driver 143 operates in response to a control signal CTR. The control signal CTR may have a voltage generated by a programmable linear regulator, but the present inventive concept is not limited thereto. For instance, the control signal CTR may have a fixed voltage value.
The low side driver 144 receives the voltage Vplus of the input node Nin1, and outputs a low side driving voltage Vc12. The low side driving voltage Vc12 and the voltage Vplus are synchronized in phase. The low side driving voltage Vc12 is provided to the low side switching circuit 120. The low side driver 144 operates in response to the control signal CTR. The low side driving voltages Vc11 and Vc12 will be described with reference to
The low side driving voltage Vc11 is provided to a gate terminal of the switching transistor T11, and the low side driving voltage Vc12 is provided to a gate terminal of the switching transistor T12.
In
For the convenience of description, the waveforms of
In,
The waveform of the low side driving voltage Vc12 is represented by a solid line. The low side driving voltage Vc12 and the voltage Vplus of the input node Nin1 are synchronized in phase. The low side driving voltage Vc12 has a waveform of which amplitude is cut off by the maximum gate voltage CL allowed by the switching transistor T12 (refer to
For the convenience of description, the waveforms of
Although not illustrated in
Input currents Iplus and Iminus are generated based on the AC voltage Vac, and are provided to input nodes Nin1 and Nin2, respectively, of the rectifier circuit 200. For example, for a half period of the AC voltage Vac, the input current Iplus is provided to the input node Nin1. Accordingly, the input node Nin1 has a voltage Vplus corresponding to the half period of the AC voltage Vac. For the other half period of the AC voltage Vac, the input current Iminus is provided to the input node Nin2. Accordingly, the input node Nin2 has a voltage Vminus corresponding to the other half period of the AC voltage Vac. The phase difference of the voltage Vplus of the input node Nin1 and the voltage Vminus of the input node Nin2 may be 180°. Descriptions of waveforms of the voltages Vplus and Vminus of the input nodes Nin1 and Nin2 have been made with reference to
The low side switching circuit 220 is connected between a reference node Nref and the input nodes Nin1 and Nin2. The reference node Nref is grounded, but the present inventive concept is not limited thereto. The low side switching circuit 220 includes low side transistors T21 and T22. The low side transistors T21 and T22 are n-channel metal oxide semiconductor (NMOS) transistors. One terminal of the low side transistor T21 is connected to the reference node Nref, and the other terminal of the low side transistor T21 is connected to the input node Nin1. Further, one terminal of the low side transistor T22 is connected to the reference node Nref, and the other terminal of the low side transistor T22 is connected to the input node Nin2.
The high side switching circuit 230 is connected between the input nodes Nin1 and Nin2 and an output node Nout. The high side switching circuit 230 includes high side transistors T23 and T24. The high side transistors T23 and T24 are NMOS transistors. One terminal of the high side transistor T23 is connected to the input node Nin1, and the other terminal of the high side transistor T23 is connected to the output node Nout. Further, one terminal of the high side transistor T24 is connected to the input node Nin2, and the other terminal of the high side transistor T24 is connected to the output node Nout.
The AC voltage Vac is converted into the rectified voltage Vrect by a circuit including the low side transistors T21 and T22, which are included in the low side switching circuit 220, and the high side transistors T23 and T24, which are included in the high side switching circuit 230. The rectified voltage Vrect is outputted from the output node Nout. The low side switching circuit 220 is controlled by the low side drivers 245 and 246, and the high side switching circuit 230 is controlled by the high side drivers 265 and 266.
The low side driver 245 receives the voltage Vminus of the input node Nin2, and outputs a low side driving voltage Vc21. The low side drive voltage Vc21 and the voltage Vminus of the input node Nin2 are synchronized in phase. The low side driving voltage Vc21 is provided to the low side switching circuit 220. The low side driver 245 operates in response to a control signal CTR. The control signal CTR may have a voltage generated by a programmable linear regulator, but the present inventive concept is not limited thereto. The control signal CTR may have a fixed voltage value.
The low side driver 246 receives the voltage Vplus of the input node Nin1, and outputs a low side driving voltage Vc22. The low side driving voltage Vc22 and the voltage Vplus of the input node Nin1 are synchronized in phase. The low side driving voltage Vc22 is provided to the low side switching circuit 220. The low side driver 246 operates in response to the control signal CTR. Descriptions of waveforms of the low side driving voltages Vc21 and Vc22 have been made with reference to
The low side switching circuit 220 includes the low side transistors T21 and T22. The low side driving voltage Vc21 is provided to a gate terminal of the low side transistor T21, and the low side driving voltage Vc22 is provided to a gate terminal of the low side transistor T22.
The bootstrap circuits 255 and 256 generate bootstrapping voltages Vb21 and Vb22. For example, the bootstrap circuit 255 outputs the bootstrapping voltage Vb21 generated based on a bootstrap driving voltage VBD1 and the voltage Vminus of the input node Nin2, and the bootstrap circuit 256 outputs the bootstrapping voltage Vb22 generated based on the bootstrap driving voltage VBD1 and the voltage Vplus of the input node Nin1. The bootstrap driving voltage VBD1 may have a voltage generated by a programmable linear regulator, but the present inventive concept is not limited thereto. The bootstrap driving voltage VBD1 may have a fixed voltage value.
The bootstrap circuit 255 includes a diode Db21 and a capacitor Cb21. The diode Db21 and the capacitor Cb21 are connected in series between a node for receiving the bootstrap driving voltage VBD1 and the input node Nin2. For example, an anode of the diode Db21 is connected to the node for receiving the bootstrap driving voltage VBD1, and one terminal of the capacitor Cb21 is connected to the input node Nin2. Further, a cathode of the diode Db21 is connected to the other terminal of the capacitor Cb21. The bootstrapping voltage Vb21 corresponds to a voltage of a node at which the diode Db21 and the capacitor Cb21 are connected to each other.
The bootstrap circuit 256 includes a diode Db22 and a capacitor Cb22. The diode Db22 and the capacitor Cb22 are connected in series between the node for receiving the bootstrap driving voltage VBD1 and the input node Nin1. For example, an anode of the diode Db22 is connected to the node for receiving the bootstrap driving voltage VBD1, and one terminal of the capacitor Cb22 is connected to the input node Nin1. Further, a cathode of the diode Db22 is connected to the other terminal of the capacitor Cb22. The bootstrapping voltage Vb22 corresponds to a voltage of a node at which the diode Db22 and the capacitor Cb22 are connected to each other.
The high side drivers 265 and 266 generate high side driving voltages Vd21 and Vd22. The high side driving voltages Vd21 and Vd22 are provided to the high side switching circuit 230. The waveforms of the high side driving voltages Vd21 and Vd22 may correspond to bootstrapped waveforms of the low side driving voltage Vc21 and Vc22, respectively. Descriptions of a relation between the high side driving voltages Vd21 and Vd22 and the low side driving voltage Vc21 and Vc22 will be made with reference to
The high side driver 265 generates the high side driving voltage Vd21 based on at least one of the rectified voltage Vrect, the voltage Vminus, the low side driving voltage Vc22, the bootstrap driving voltage VBD1, and the bootstrapping voltage Vb21. In this case, a wire or line corresponding to a voltage not being used to generate the high side driving voltage Vd21 from among the rectified voltage Vrect, the voltages Vplus and Vminus respectively provided from the input nodes Nin1 and Nin2, the low side driving voltage Vc22, the bootstrap driving voltage VBD1, and the bootstrapping voltage Vb21 need not be provided or may be floated. Alternatively, the high side driver 265 further include a control circuit (not shown) for controlling a connection of a wire or line being used to generate the high side driving voltage Vd21 and a connection of the wire or line not being used to generate the high side driving voltage Vd21. The high side driver 265 provides the high side driving voltage Vd21 to the high side switching circuit 230. The high side switching circuit 230 includes the high side transistor T23, and the high side driving voltage Vd21 is provided to a gate terminal of the side transistor T23.
The high side driver 266 generates the high side driving voltage Vd22 based on at least one the rectified Vrect, the voltage Vplus, the low side driving voltage Vc21, the bootstrap driving voltage VBD1, and the bootstrapping voltage Vb22. In this case, if a voltage is not used to generate the high side driving voltage Vd22, such unused voltage need not be provided to the high side driver or a wire or line supplying the unused voltage may be floated. Alternatively, the high side driver 266 may further include a control circuit (not shown) for controlling a connection of a wire or line being used to generate the high side driving voltage Vd22 and a connection of the wire or line not being used to generate the high side driving voltage Vd22. The high side driver 266 provides the high side driving voltage Vd22 to the high side switching circuit 230. The high side switching circuit 230 includes the high side transistor T24, and the high side driving voltage Vd22 is provided to a gate terminal of the side transistor T24. Descriptions of the high side driver 265 and 266 will be made with reference to
As shown in
As described with reference to
For the convenience of description, the waveforms of
Although not illustrated in
According to an exemplary embodiment of the present inventive concept, power loss due to a switching may be reduced. Further, the rectifier circuit according to the example embodiments described in
The level shifter 310 shifts a level of an input signal IN. In the level shifter 310, four driving voltages VDDH, VSSH, VDDL and VSSL are provided. The level of the input signal IN is shifted by a circuit including four inverters INV1, INV2, INV3 and INV4, four p-channel metal oxide semiconductor (PMOS) transistors MP1, MP2, MP3 and MP4, four NMOS transistors MN1, MN2, MN3 and MN4, two p-type lateral double diffused metal oxide semiconductor (LDMOS) transistors LDP1 and LDP2, two n-type LDMOS transistors LDN1 and LDN2, and an electrostatic detection resistance RESD. Operations of the level shifter 310 illustrated in
The latch 330 latches the output signals OUT and /OUT of the level shifter 310. The output signals OUT and /OUT is latched by a circuit including two NAND gates NA1 and NA2. Operations of the latch 330 are well known, and thus detailed descriptions of the latch 330 will be omitted. The latch 330 is presented for the convenience of description, and the present inventive concept is not limited thereto. The latch 330 may have a different configuration from that illustrated in
The pull-up signal generator 340 generates pull-up signals PU1 and PU2 based on the latched output signal of the latch 330 and the output signals OUT and /OUT. A NAND gate NA3 included in the pull-up signal generator 340 performs a NAND logical operation on the output signals OUT and /OUT and a reset signal RST1. If the reset signal RST1 has logic ‘0’, a pull-up signal is triggered. For example, if the reset signal RST1 has logic ‘0’, the pull-up signals PU1 and PU2 are generated according to the latched output signals of the latch 330. An OR gate OR1 performs an OR logical operation on an output of the NAND gate NA3 and the latched output signal OUT to generate the pull-up signal PU1. An OR gate OR2 performs an OR logical operation on the output of the NAND gate NA3 and the latched output signal /OUT to generate the pull-up signal PU2.
The pull-up circuit 350 may cause the level shifter 310 to output the driving voltage VDDH as the output signal OUT in response to the pull-up signal PU1. For example, the pull-up circuit 350 includes a PMOS transistor MPS. For example, when the output signal OUT needs to have the driving voltage VDDH or a voltage near the driving voltage VDDH, a pull-up transistor MP3 is controlled to supply the driving voltage VDDH to an output of an inverter formed of two transistors MP3 and MN3.
The pull-up circuit 360 causes the level shifter 310 to output the driving voltage VDDH as the output signal /OUT in response to the pull-up signal PU2. The pull-up circuit 360 includes a PMOS transistor MP6. For example, when the output signal /OUT needs to have the driving voltage VDDH or a voltage near the driving voltage VDDH, a pull-up transistor MP4 is controlled to supply the driving voltage VDDH to an output of an inverter formed of two transistors MP4 and MN4.
The high side driver 300 is included in the rectifier circuit 200 as the high side driver 265 or 266 of
Referring to
The high side driving voltage Vd21 is generated as the output signal /OUT by shifting a level of the low side driving voltage Vc22 provided as the input signal IN. For example, the pull-up circuit 360 (refer to
The high side driver 266 generates a high side driving voltage Vd22 based on the voltage Vminus provided from the input node Nin2, a low side driving voltage Vc21, and a bootstrapping voltage Vb22. The high side driver 266 of
The high side driving voltage Vd22 is generated as the output signal /OUT by shifting a level of the low side driving voltage Vc21 provided as the input signal IN. For example, the pull-up circuit 360 included in the high side driver 266 causes the high side driving voltage Vd22 to have the bootstrapping voltage Vb22 in response to the pull-up signal PU2. For example, a driving voltage VDDL is a voltage having a fixed voltage such as 3V, 4V or 5V, and a driving voltage VSSL is a ground voltage. However, the present inventive concept is not limited thereto. Further, in this example embodiment, wires or lines corresponding to the rectified voltage Vrect, the voltage Vplus provided from the input node Nin1, and the bootstrap driving voltage VBD1, which are not used to generate the high side driving voltage Vd22, need not be provided or may be floated. Alternatively, the high side driver 266 may further include a control circuit (not shown) for controlling connections of wires or lines being used to generate the high side driving voltage Vd22 and connections of the wires or lines not being used to generate the high side driving voltage Vd22.
In the high side driver 300 of
The bias current generator 410 receives a driving voltage VDD1. A bias current BC is generated in the bias current generator 410. The bias current BC is provided to the current mode comparator 420. The bias current generator 410 includes a first-type first current mirror CM11.
The first-type first current mirror CM11 provides the bias current BC to the current mode comparator 420. The first-type first current mirror CM11 may be an NMOS type current mirror that operates using a ground voltage. A configuration of a current mirror is well known to those of ordinary skilled in the art. Thus, detailed descriptions of the current mirror CM11 will be omitted.
The current mode comparator 420 generates a comparison signal CMP corresponding to a comparison result of amplitude of a first comparison target voltage Vt1 and a second comparison target voltage Vt2. For example, the comparison signal CMP is generated from the comparison result of amplitude of the first comparison target voltage Vt1 and the second comparison target voltage Vt2. The current mode comparator 420 generates the comparison signal CMP by using the bias current BC provided from the bias current generator 410. The current mode comparator 420 includes a second-type first current mirror CM21, a first-type second current mirror CM12, a second-type second current mirror CM22, and a first-type third current mirror CM13.
The second-type first current mirror CM21 outputs current provided from the first-type first current mirror CM11. The second-type first current mirror CM21 is a PMOS type current mirror that operates using the second comparison target voltage Vt2. The first-type second current mirror CM12 outputs current provided from the second-type first current mirror CM21. The first-type second current mirror CM12 may be an NMOS type current mirror. The second-type second current mirror CM22 outputs current provided from the first-type second current mirror CM12. The second-type second current mirror CM22 may be a PMOS type current mirror that operates using the first comparison target voltage Vt1. The first-type third current mirror CM13 outputs current provided from the second-type second current mirror CM22. The first-type third current mirror CM13 may be an NMOS type current mirror that operates using the ground voltage. Using such arrangements of the current mirrors CM21, CM22, CM12 and CM13, the comparison signal CMP is generated based on the current outputted from the second-type first current mirror CM21 and current outputted from the first-type third current mirror CM13. The comparison signal CMP is generated depending on the comparison result of amplitude of the first comparison target voltage Vt1 and the second comparison target voltage Vt2.
The level shifter 430 generates an intermediate signal Vinter. The intermediate signal Vinter is generated based on the comparison signal CMP. Descriptions of the intermediate signal Vinter will be described with reference to
The first-type fourth current mirror CM14 outputs current provided from the second-type first current mirror CM21. The first-type fourth current mirror CM14 may be an NMOS type current mirror. The comparison control transistor CCN receives the comparison signal CMP from the current mode comparator 420. The comparison signal CMP is provided to a gate terminal of the comparison control transistor CCN. The comparison control transistor CCN receives current outputted from the first-type fourth current mirror CM14 through its one terminal. The comparison control transistor CCN controls flowing of the received current according to the comparison signal CMP. The comparison control transistor CCN is an NMOS transistor. The second-type third current mirror CM23 outputs current provided from the comparison control transistor CCN. The second-type third current mirror CM23 may be a PMOS type current mirror. The second-type fourth current mirror CM24 outputs current provided from the first-type fourth current mirror CM14. The second-type fourth current mirror CM24 may be a PMOS type current mirror that operates using the drive voltage VDD2. The first-type fifth current mirror CM15 outputs current provided from the second-type fourth current mirror CM24. The first-type fifth current mirror CM15 may be an NMOS type current mirror that operates using the first comparison target voltage Vt1. Using such arrangements of the current mirrors CM23, CM24, CM15 and CM14, the intermediate signal Vinter is generated based on current outputted from the second-type third current mirror CM23 and current outputted from the first-type fifth current mirror CM15. In this case, the current outputted from the second-type third current mirror CM23 may be greater than the current outputted from the first-type fifth current mirror CM15. Accordingly, the intermediate signal Vinter is a shifted level.
The high side driver 400 may be included in the rectifier circuit 200 as the high side driver 265 or 266 of the present inventive concept. However, the high side driver 400, if not used in the rectifier circuit 200 of
Referring to
The intermediate signal Vinter generated by the level shifter 430 is used to generate a high side driving voltage Vd21. The intermediate signal Vinter is inverted through the inverter INV5. For example, the inverter INV5 inverts the intermediate signal Vinter.
The inverted intermediate signal Vinter is outputted as an output voltage Vout through the output circuit 450. The output voltage Vout is provided to a high side transistor T23 as the high side driving voltage Vd21. The output circuit 450 includes a latch 452 and a buffer 454. The latch 452 is connected to prevent a shoot-through current from flowing through the high side transistor T23. The operations of the latch 452 are controlled according to a reset signal RST2. The reset signal RST2 may have a level obtained by shifting a level of a voltage for controlling a low side transistor T21. The buffer 454 buffers an output of the latch 452 to output the output voltage Vout.
The high side driver 265 generates a high side driving voltage Vd21 based on a rectified voltage Vrect, a voltage Vplus provided from an input node Nin1 (refer to
The high side driver 265 includes the high side driver 400 of
The high side driver 266 generates a high side driving voltage Vd22 based on the rectified voltage Vrect, the voltage Vplus provided from the input node Nin1, the voltage Vminus provided from the input node Nin2, the bootstrap driving voltage VBD1, and a bootstrapping voltage Vb22. A node having the bootstrapping voltage Vb22 and the input node Nin2 are connected to each other.
The high side driver 266 includes the high side driver 400 of
In the high side driver 400 described with reference to
Input currents Iplus and Iminus are generated based on the AC voltage Vac, and are provided to input nodes Nin1 and Nin2, respectively, of the rectifier circuit 500. For example, the input current Iplus is provided to the input node Nin1 based on a signal corresponding to a half period of the AC voltage Vac. Accordingly, the input node Nin1 has a voltage Vplus corresponding to the half period of the AC voltage Vac. Further, the input current Iminus is provided to the input node Nin2 based on the other half period of the AC voltage Vac. Accordingly, the input node Nin2 has a voltage Vminus corresponding to the other half period of the AC voltage Vac. A phase difference between the voltage Vplus and the voltage Vminus may be 180°. Descriptions of the voltages Vplus and Vminus of the input nodes Nin1 and Nin2 have been made with reference to
The low side switching circuit 520 is connected between a reference node Nref and the input nodes Nin1 and Nin2. The reference node Vref is grounded, but the present inventive concept is not limited thereto. The low side switching circuit 520 includes low side transistors T51 and T52. The low side transistors T51 and T52 are an NMOS transistor. For example, one terminal of the low side transistor T51 is connected to the reference node Nref, and the other terminal of the low side transistor T52 is connected to the input node Nin1. One terminal of the low side transistor T52 is connected to the reference node Nref, and the other terminal of the low side transistor T52 is connected to the input node Nin2.
The high side switching circuit 530 is connected between the input nodes Nin1 and Nin2 and an output node Nout. The high side switching circuit 530 includes high side transistors T53 and T54. The high side transistors T53 and T54 are PMOS transistors. In this case, one terminal of the high side transistors T53 is connected to the output node Nout, and the other terminal of the high side transistors T53 is connected to the input node Nin1. One terminal of the high side transistors T54 is connected to the output node Nout, and the other terminal of the high side transistors T54 is connected to the input node Nin2.
As an example embodiment, the rectifier circuit 500 further include a substrate voltage generator 535. The substrate voltage generator 535 generate a substrate voltage Vsub. The substrate voltage Vsub are generated based on the voltage Vplus and Vminus provided from the input nodes Nin1 and Nin2. The substrate voltage Vsub is applied to the high side transistors T53 and T54 included in the high side switching circuit 530. The substrate voltage generator 535 includes four diodes Ds1, Ds2, Ds3, and Ds4. The configuration of the substrate voltage generator 535 illustrated in
The AC voltage Vac is converted into the rectified voltage Vrect by a circuit including the low side transistors T51 and T52 and the high side transistors T53 and T54. The rectified voltage Vrect is outputted from the output node Nout. For example, the low side switching circuit 520 is controlled by the low side drivers 545 and 546, and the high side switching circuit 530 is controlled by the bootstrap circuits 555 and 556.
The low side driver 545 receives the voltage Vminus of the input node Nin2 to output a low side driving voltage Vc51. The low side driving voltage Vc51 and the voltage Vminus of the input node Nin2 are synchronized in phase. The low side driving voltage Vc51 is provided to the low side switching circuit 520. The low side driver 545 operates in response to a control signal CTR. The control signal CTR has a voltage generated by a programmable linear regulator, but the present inventive concept is not limited thereto. The control signal CTR may have a fixed voltage value.
The low side driver 546 receives the voltage Vplus of the input node Nin1 to output a low side driving voltage Vc52. The low side driving voltage Vc52 and the voltage Vplus of the input node Nin1 are synchronized in phase. The low side driving voltage Vc52 is provided to the low side switching circuit 520. The low side driver 546 operates in response to the control signal CTR. Descriptions of waveforms of the low side driving voltages Vc51 and Vc52 have been made with reference to
The low side switching circuit 520 includes the low side transistors T51 and T52. The low side driving voltage Vc51 is provided to a gate terminal of the low side transistor T51, and the low side driving voltage Vc52 is provided to a gate terminal of the low side transistor T52.
The bootstrap driving voltage generator 550 generates a bootstrap driving voltage VBD2. The bootstrap driving voltage VBD2 is generated based on the rectified voltage Vrect, a voltage corresponding to the control signal CTR, and an offset voltage Voffset. The offset voltage Voffset may be adjustable. A value of the bootstrap driving voltage VBD2 is adjusted by adjusting the value of the offset voltage Voffset. For example, the value of the bootstrap driving voltage VBD2 may be obtained by adding the value of the offset voltage Voffset to a value obtained by subtracting a value of the voltage corresponding to the control signal CTR from a value of the rectified voltage Vrect (i.e., VBD2=Vrect−CTR+Voffset). The present inventive concept is not limited thereto.
The bootstrap circuits 555 and 556 generate bootstrapping voltages Vb51 and Vb52. The bootstrap circuit 555 outputs the bootstrapping voltage Vb51, which is generated based on the bootstrap driving voltage VBD2 and the low side driving voltage Vc51. The bootstrapping voltage Vb51 is provided to the high side switching circuit 530. The high side switching circuit 530 includes the high side transistor T53. The bootstrapping voltage Vb51 is provided to a gate terminal of the high side transistor T53.
The bootstrap circuit 556 outputs the bootstrapping voltage Vb52, which is generated based on the bootstrap driving voltage VBD2 and the low side driving voltage Vc52. The bootstrapping voltage Vb52 is provided to the high side switching circuit 530. The high side switching circuit 530 includes the high side transistor T54. The bootstrapping voltage Vb52 is provided to a gate terminal of the high side transistor T54. Relations between the low side driving voltages Vc51 and Vc52 and the bootstrapping voltages Vb51 and Vb52 is similar to a relation between the low side driving voltage Vc21 and the high side driving voltage Vd21 illustrated in
The bootstrap circuit 555 includes a diode Db51 and a capacitor Cb51. The diode Db51 and the capacitor Cb51 are connected in series between a node for receiving the bootstrap driving voltage VBD2 and a node having the low side driving voltage Vc51. For example, an anode of the diode Db51 is connected to the node for receiving the bootstrap driving voltage VBD2, and one terminal of the capacitor Cb51 is connected to the node having the low side driving voltage Vc51. Further, a cathode of the diode Db51 is connected to the other terminal of the capacitor Cb51. In this case, the bootstrapping voltage Vb51 is a voltage of a node at which the diode Db51 and the capacitor Cb51 are connected to each other.
The bootstrap circuit 556 includes a diode Db52 and a capacitor Cb52. The diode Db52 and the capacitor Cb52 are connected in series between the node for receiving the bootstrap drive voltage VBD2 and a node having the low side driving voltage Vc52. In particular, an anode of the diode Db52 is connected to the node for receiving the bootstrap drive voltage VBD2, and one terminal of the capacitor Cb52 is connected to the node having the low side driving voltage Vc52. Further, a cathode of the diode Db52 is connected to the other terminal of the capacitor Cb52. In this example embodiment, the bootstrapping voltage Vb52 is a voltage of a node at which the diode Db52 and the capacitor Cb52 are connected to each other.
In
For the convenience of description, it is assumed that the power transferring system 1000 is a wireless charging system using a magnetic resonance between inductive elements. The power transferring system 1000 be applicable to other types of systems.
The rectifier circuit 1110 receives an AC voltage Vac from a transmitter Tx of the power transferring system 1000. The rectifier circuit 1110 rectifies the received AC voltage Vac. For example, the rectifier circuit 1110 converts the received AC voltage Vac into a rectified voltage Vrect. The configuration of the rectifier circuit 1110 is described with reference to
The buck converter 1130 receives the rectified voltage Vrect. The buck converter 1130 operates by using a first operation voltage Vop1 generated by the high voltage linear regulator 1170. The buck converter 1130 outputs a charging voltage Vcharge based on the rectified voltage Vrect. The buck converter 1130 converts the rectified voltage Vrect having a fluctuating value into the charging voltage Vcharge having a relatively stable value.
The charger 1150 generates charging current Icharge based on the charging voltage Vcharge. The charging current Icharge is provided to the battery 1155. The amount of charges charged in the battery 1150 increases by increasing the charging current Icharge.
The high voltage linear regulator 1170 receives the rectified voltage Vrect. The high voltage linear regulator 1170 generates the first operation voltage Vop1 for operating the buck converter 11130 based on the rectified voltage Vrect. Further, the high voltage linear regulator 1170 generates a second operation voltage Vop2 for operating the LDO regulator 1190 based on the rectified voltage Vrect.
The high voltage linear regulator 1170 serves as a power supply device for operating the power transferring device 1100. For example, the high voltage linear regulator 1170 converts the rectified voltage Vrect having a fluctuating value into the first and second operation voltages Vop1 and Vop2 having a relatively stable value.
The LDO regulator 1190 operates by using the second operation voltage Vop2 generated by the high voltage linear regulator 1170. The low-dropout regulator 1190 outputs an output voltage V_OUT based on the second operation voltage Vop2. The output voltage V_OUT generated by the LDO regulator 1190 is provided to the RF/digital circuit block 1199.
The RF/digital circuit block 1199 operates by using the output voltage V_OUT. The RF/digital circuit block 1199 transmits a voltage control signal V_CON to the transmitter Tx of the power transferring system 1000. Descriptions of the voltage control signal V_CON will be made with reference to
The buck converter 1310 of the transmitter Tx transfers power to the transmitting inductor LTx. The rectifier circuit 1110 receives an AC voltage Vac from the transmitting inductor LTx by magnetic resonance. The rectifier circuit 1100 rectifies the received AC voltage Vac. For example, the rectifier circuit 1100 converts the received AC voltage Vac into the rectified voltage Vrect. The rectifier circuit 1110 may be configured according to an exemplary embodiment of the present inventive concept. For example, the rectifier circuit 110 may be configured according to the exemplary embodiments of
The RF/digital circuit block 1199 operates by using the output voltage V_OUT. The RF/digital circuit block 1199 transmits a voltage control signal V_CON to the RF circuit 1330 of the transmitter Tx. The voltage control signal V_CON is a signal for controlling amplitude of the AC voltage Vac being provided to the rectifier circuit 1110. By controlling amplitude of the AC voltage Vac based on the voltage control signal V_CON, amplitude of a voltage being provided to components included in the receiver Rx of the power transferring system 1000 is adjusted.
The voltage control signal V_CON is provided to the MCU 1350 through the RF circuit 1330. The MCU 1350 controls the buck converter 1310 based on the voltage control signal V_CON. The buck converter 1310 adjusts amplitude of power being transferred to the transmitting inductor LTx according to a control of the MCU 1350. As a result, amplitude of the AC voltage Vac being provided to the rectifier circuit 1110 is adjusted.
The battery 2100 is charged by using charging current Icharge. When the battery 2100 is connected to the portable electronic device after being charged, the battery 2100 outputs a battery voltage Vbat. The battery voltage Vbat is provided to the PMIC 2300. The PMIC 2300 converts the battery voltage Vbat provided from the battery 2100 into a stable voltage. The PMIC 2300 provides the stable voltage to other components. Each of the AP 2500, the input/output interface 2510, the memory 2520, the storage 2530, the display 2540, and the communication circuit block 2550 operates by using the stable voltage provided from the PMIC 2300.
While the present inventive concept has been shown and described with reference to exemplary embodiments thereof, it will be apparent to those of ordinary skill in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the inventive concept as defined by the following claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2014-0088464 | Jul 2014 | KR | national |
