WO2022251997A1 - 功率电路和电子设备 - Google Patents
功率电路和电子设备 Download PDFInfo
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- WO2022251997A1 WO2022251997A1 PCT/CN2021/097147 CN2021097147W WO2022251997A1 WO 2022251997 A1 WO2022251997 A1 WO 2022251997A1 CN 2021097147 W CN2021097147 W CN 2021097147W WO 2022251997 A1 WO2022251997 A1 WO 2022251997A1
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Classifications
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- H03F3/72—Gated amplifiers, i.e. amplifiers which are rendered operative or inoperative by means of a control signal
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
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- H03F3/00—Amplifiers with only discharge tubes or only semiconductor devices as amplifying elements
- H03F3/20—Power amplifiers, e.g. Class B amplifiers, Class C amplifiers
- H03F3/24—Power amplifiers, e.g. Class B amplifiers, Class C amplifiers of transmitter output stages
- H03F3/245—Power amplifiers, e.g. Class B amplifiers, Class C amplifiers of transmitter output stages with semiconductor devices only
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- H03F1/00—Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
- H03F1/02—Modifications of amplifiers to raise the efficiency, e.g. gliding Class A stages, use of an auxiliary oscillation
- H03F1/0205—Modifications of amplifiers to raise the efficiency, e.g. gliding Class A stages, use of an auxiliary oscillation in transistor amplifiers
- H03F1/0211—Modifications of amplifiers to raise the efficiency, e.g. gliding Class A stages, use of an auxiliary oscillation in transistor amplifiers with control of the supply voltage or current
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- H03F1/0205—Modifications of amplifiers to raise the efficiency, e.g. gliding Class A stages, use of an auxiliary oscillation in transistor amplifiers
- H03F1/0261—Modifications of amplifiers to raise the efficiency, e.g. gliding Class A stages, use of an auxiliary oscillation in transistor amplifiers with control of the polarisation voltage or current, e.g. gliding Class A
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- H03F2203/7236—Indexing scheme relating to gated amplifiers, i.e. amplifiers which are rendered operative or inoperative by means of a control signal the gated amplifier being switched on or off by putting into parallel or not, by choosing between amplifiers by (a ) switch(es)
Definitions
- the present application relates to the technical field of power electronics, and more specifically, to a power circuit and electronic equipment.
- Power circuits such as power amplifier circuits or digital-to-analog conversion circuits, charging circuits, etc.
- communication or radar systems often need to be turned on or off at specific times according to protocol or application requirements. Since the opening or closing of the power circuit will cause large voltage fluctuations on the power supply, it will also accelerate the aging of devices in the power circuit (such as power tubes, etc.), affecting the reliability and life of the power circuit.
- the embodiment of the present application provides a power circuit and electronic equipment, which can slowly increase or decrease the voltage of the power supply when the power circuit and electronic equipment are turned on or off, thereby reducing the impact of the power circuit and electronic equipment on the power supply, and realizing The effective control of the voltage fluctuation on the power supply improves the stability of the power supply.
- the embodiment of the present application provides a power circuit.
- the power circuit may be a power amplifier circuit or a digital-to-analog conversion circuit, etc., which can slowly increase or decrease the voltage of the power supply when the power circuit is turned on or off.
- the embodiment of the application does not limit the specific form of the power circuit.
- the power circuit provided in the embodiment of the present application may include a power module and a power supply module coupled with the power module.
- the power module is configured to supply power in a time-sharing power-on manner.
- time-division power-on method of the power module may include but not limited to the following two situations:
- Case 1 The power supply module supplies power to the power module in a time-sharing manner.
- the power supply module may provide power supply current to the power module in a time-sharing power-on manner, or the power supply module may provide power supply voltage to the power module in a time-division power-on manner.
- the supply current is used to indicate the output current of the power supply module
- the supply voltage is used to indicate the output voltage of the power supply module.
- the power module is configured to be powered on based on the supply current or the supply voltage provided by the power supply module. That is to say, the power module controls the static working current of the power module based on the supply current or the supply voltage provided by the power supply module.
- Case 2 On the basis of the power supplied by the power supply module, the power module itself is powered on in a time-sharing manner.
- the power supply of the power supply module can be that the power supply module provides the power supply current for the power module (please refer to the above introduction for the supply current), or it can be that the power supply module provides the power supply voltage for the power module (please refer to the above introduction for the supply voltage).
- the power module based on the supply current or voltage provided by the power supply module, the power module is powered on in a time-sharing manner. That is to say, the power module controls the static working current of the power module based on the supply current or the supply voltage provided by the power supply module.
- the power circuit provided by the embodiment of the present application supplies power through the power module in a time-sharing power-on manner, so that the voltage of the power supply increases slowly during the power circuit startup process, thereby reducing the power module (or power circuit) at the moment of startup.
- the impact of the power module on the power supply improves the stability of the power supply.
- the time-sharing power-on method improves the reliability of the power circuit and reduces the cost of the power circuit.
- the power circuit provided by the embodiment of the present application can also stop the power supply through the power module in a time-sharing manner, so that the voltage of the power supply decreases slowly during the shutdown process of the power circuit, thereby reducing the power module (also can be said It is the power circuit)
- the impact of the power module on the power supply at the moment of shutdown improves the stability of the power supply.
- the time-sharing power-off method can also improve the reliability of the power circuit, reduce the size of the power circuit, and reduce the cost of the power circuit.
- the power supply module may include multiple power supply subunits; the multiple power supply subunits may be coupled with respective control signal lines, and a delay unit is coupled between the control signal lines.
- the control signal line controls the power supply module to supply power to the power module in a time-sharing power-on manner according to the time delay set by the delay unit.
- the power module may include multiple power subunits; the power supply module is used to supply power to the multiple power subunits in a time-divided power-on manner.
- the power supply subunit may include a current source unit, and the current source unit includes a current source.
- the current source is configured to supply power to the power module in a time-sharing power-on manner, that is, the current source provides power supply current to the power module in a time-sharing power-on manner.
- the current source in the current source unit itself has a timing control function.
- the power supply unit may include a current source unit and a switch unit; the current source unit includes multiple current sources, the switch unit includes multiple switches, and the multiple current sources are coupled to the multiple switches one by one .
- the plurality of switches are configured to: control the plurality of current sources to supply power to the power module based on the control signal provided by the control signal line, that is, the plurality of switches control the plurality of current sources to supply power to the power module based on the control signal provided by the control signal line
- the module supplies the supply current.
- a current source with a sequence control function in the above-mentioned current source unit or multiple current sources and multiple switches in the current source unit can provide slow power for the power module. changing supply current.
- the power supply subunit may include a voltage source unit, and the voltage source unit includes a voltage source.
- the voltage source is configured to supply power to the power module based on the control signal provided by the control signal line, that is, the voltage source provides a power supply voltage to the power module based on the control signal provided by the control signal line.
- the power supply module may further include a bias unit, the input terminal of the bias unit is coupled to the output terminals of the plurality of power supply subunits, and the output terminal of the bias unit is coupled to the input terminal of the power module;
- the power supply sub-unit is further configured to: provide a power supply current for the bias unit.
- the bias unit is configured to provide the power module with a supply voltage based on the supply current.
- the above-mentioned bias unit may include any one of a triode, a field effect transistor or an IGBT (insulated gate bipolar transistor, that is, an insulated gate bipolar transistor).
- IGBT insulated gate bipolar transistor
- the power supply voltage can be obtained based on the power supply current output by the current source, and the power supply voltage can be provided to the power module, and then the static working current of the power module can be controlled through the power supply voltage, that is, the power supply voltage from the bias unit can be realized. Control the static working current of the power module.
- the power module may include multiple power subunits; the power supply module is used to supply power to the multiple power subunits in a time-divided power-on manner.
- the power subunit includes a power transistor and a load impedance.
- the control pole of the power tube is coupled to the output terminal of the power supply module, the first pole of the power tube is coupled to the power supply terminal through the load impedance, and the second pole of the power tube is coupled to the ground terminal.
- the power transistor may be a triode.
- the base of the triode is coupled to the output terminal of the power supply module through the corresponding first switch, the collector of the triode is coupled to the power supply terminal through the load impedance, and the emitter of the triode is coupled to the ground terminal.
- the power transistor may be a field effect transistor.
- the gate of the field effect transistor is coupled to the output terminal of the power supply module through the corresponding first switch, the drain of the field effect transistor is coupled to the power supply terminal through the load impedance, and the source of the field effect transistor is coupled to the ground terminal.
- the power subunit includes multiple power transistors, multiple first switches, and load impedances, and the multiple power transistors correspond to the multiple first switches one by one.
- the control pole of the power transistor is coupled to the output terminal of the power supply module through the corresponding first switch, the first pole of the power transistor is coupled to the power supply terminal through the load impedance, and the second pole of the power transistor is coupled to the ground terminal.
- the power transistor may be a triode.
- the base of the triode is coupled to the output terminal of the power supply module through the corresponding first switch, the collector of the triode is coupled to the power supply terminal through the load impedance, and the emitter of the triode is coupled to the ground terminal.
- the power transistor may be a field effect transistor.
- the gate of the field effect transistor is coupled to the output terminal of the power supply module through the corresponding first switch, the drain of the field effect transistor is coupled to the power supply terminal through the load impedance, and the source of the field effect transistor is coupled to the ground terminal.
- the power subunit includes multiple power transistors, multiple second switches, and load impedances, and the multiple power transistors correspond to the multiple second switches one by one.
- the control pole of the power tube is coupled to the output terminal of the power supply module, the first stage of the power tube is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the second pole of the power tube is coupled to the ground terminal.
- the power transistor may be a triode.
- the base of the triode is coupled to the output terminal of the power supply module, the collector of the triode is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the emitter of the triode is coupled to the ground terminal.
- the power transistor may be a field effect transistor.
- the gate of the field effect transistor is coupled to the output terminal of the power supply module, the drain of the field effect transistor is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the source of the field effect transistor is coupled to the ground terminal.
- the power subunit includes a plurality of power transistors, a plurality of first switches, a plurality of second switches, and a load impedance, and the plurality of power transistors, the plurality of first switches, and the plurality of second switches One to one correspondence.
- the control pole of the power transistor is coupled to the output terminal of the power supply module through the corresponding first switch, the first stage of the power transistor is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the second pole of the power transistor is coupled to the ground terminal.
- the power transistor may be a triode.
- the base of the triode is coupled to the output terminal of the power supply module through the corresponding first switch, the collector of the triode is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the emitter of the triode is coupled to the ground terminal .
- the power transistor may be a field effect transistor.
- the gate of the FET is coupled to the output terminal of the power supply module through the corresponding first switch, the drain of the FET is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the source of the FET is coupled to the ground terminal .
- the power subunit in the embodiment of the present application is not limited to the above four possible implementations (that is, the power subunit is not limited to the above four topological structures), and the power subunit can also be implemented through other topological structures based on
- the control of the power supply current to the static working current of the power module is not limited in this embodiment of the present application.
- the power subunit further includes a DC blocking capacitor and a bias inductor
- the DC blocking capacitor is arranged between the control electrode of the power transistor and the connection signal source, and the bias inductor is arranged between the control electrode of the power transistor and the bias unit of the power supply module.
- the power sub-unit further includes multiple DC blocking capacitors and multiple bias inductors, and the multiple DC blocking capacitors, multiple bias inductors and multiple power transistors correspond one-to-one;
- One end of the DC blocking capacitor is coupled to the signal source, the other end of the DC blocking capacitor is coupled to the control pole of the power tube, one end of the bias inductor is coupled to the bias unit of the power supply module, and the other end of the bias inductor is coupled to the control pole of the power tube coupling.
- the above-mentioned DC blocking capacitor plays the role of isolating the DC signal through the AC signal
- the above-mentioned bias inductance plays the role of isolating the high-frequency signal through the low-frequency signal, and can transfer the modulated signal from the signal source (it can be a single tone signal, or It can be a high-frequency AC signal, such as a high-frequency amplitude signal, a high-frequency phase signal, etc.) and a low-frequency voltage signal from the bias unit input to the power module, which improves the signal input to the power module (including modulation from the signal source) signal and the quality of the low frequency voltage signal from the bias unit).
- the power module may be a power amplifier PA (power amplifier), which is used to work in a transmission time slot in a time division duplex TDD (time division dual) mode.
- PA power amplifier
- the power module may be a low noise amplifier (LNA) for working in a receiving time slot in a time division duplex TDD mode.
- LNA low noise amplifier
- the embodiment of the present application provides a power circuit.
- the power circuit may be a power amplifier circuit or a digital-to-analog conversion circuit, etc., which can slowly increase or decrease the voltage of the power supply when the power circuit is turned on or off.
- the embodiment of the present application does not limit the specific form of the power circuit.
- the power circuit provided in the embodiment of the present application may include a power module and a power supply module coupled to the power module; the power supply module may include multiple power supply subunits.
- the plurality of power supply sub-units respectively include respective control signal lines for controlling the power supply module to supply power to the power module.
- multiple power supply sub-units supply power to the power module through their respective control signal lines.
- Multiple power supply sub-units can provide power supply current for the power module, and multiple power supply sub-units can also provide power supply voltage for the power module.
- the power supply current is used to indicate the output current of the multiple power supply sub-units
- the power supply voltage is used to indicate the output voltage of the multiple power supply sub-units.
- the power module is configured to: control the static working current of the power module based on the supply current or the supply voltage provided by the power supply module.
- the power circuit provided by the embodiment of the present application supplies power to the power module through multiple power supply sub-units in the power supply module, which reduces the impact of the power module (or power circuit) on the power supply when the power module (or power circuit) is turned on, and improves the reliability of the power supply. stability. At the same time, the reliability of the power circuit is improved, the size of the power circuit is reduced, and the cost of the power circuit is reduced.
- the power circuit provided by the embodiment of the present application can also stop supplying power to the power module sequentially through multiple power supply sub-units in the power supply module, reducing the power module (also called the power circuit) power module at the moment of shutdown.
- the impact on the power supply improves the stability of the power supply. Also, the reliability of the power circuit can be improved, the size of the power circuit can be reduced, and the cost of the power circuit can be reduced.
- a delay unit is coupled between the control signal lines.
- the delay interval set by the delay unit enables the power supply module to supply power to the power module in a time-sharing power-on manner.
- the power supply subunit may include a current source unit, and the current source unit includes a current source.
- the current source is configured to supply power to the power module by controlling its own control signal line, that is, the current source provides power supply current to the power module by controlling its own control signal line.
- the current source in the current source unit itself has a timing control function.
- the power supply unit may include a current source unit and a switch unit; the current source unit includes multiple current sources, the switch unit includes multiple switches, and the multiple current sources are coupled to the multiple switches one by one .
- the plurality of switches are configured to: control the plurality of current sources to supply power to the power module based on the control signal provided by the control signal line, that is, the plurality of switches control the plurality of current sources to supply power to the power module based on the control signal provided by the control signal line
- the module supplies the supply current.
- a current source with a sequence control function in the above-mentioned current source unit or multiple current sources and multiple switches in the current source unit can provide slow power for the power module. changing supply current.
- the power supply subunit may include a voltage source unit, and the voltage source unit includes a voltage source.
- the voltage source is configured to: supply power to the power module based on the control signal provided by the control signal line, that is, the voltage source provides the power module with a supply voltage based on the control signal provided by the control signal line.
- the power supply module may further include a bias unit, the input terminal of the bias unit is coupled to the output terminals of the plurality of power supply subunits, and the output terminal of the bias unit is coupled to the input terminal of the power module;
- the power supply sub-unit is further configured to: provide power supply current for the bias unit based on the control signal line.
- the bias unit is configured to provide the power module with a supply voltage based on the supply current.
- the above-mentioned bias unit may include any one of a triode, a field effect transistor or an IGBT.
- the power supply voltage can be obtained based on the power supply current output by the current source, and the power supply voltage can be provided to the power module, and then the static working current of the power module can be controlled through the power supply voltage, that is, the power supply voltage from the bias unit can be realized. Control the quiescent working current of the power module.
- the power module may include multiple power subunits, and the power supply module is used to supply power to the multiple power subunits respectively.
- the power subunit includes a power transistor and a load impedance.
- the control pole of the power tube is coupled to the output terminal of the power supply module, the first pole of the power tube is coupled to the power supply terminal through the load impedance, and the second pole of the power tube is coupled to the ground terminal.
- the power transistor may be a triode.
- the base of the triode is coupled to the output terminal of the power supply module through the corresponding first switch, the collector of the triode is coupled to the power supply terminal through the load impedance, and the emitter of the triode is coupled to the ground terminal.
- the power transistor may be a field effect transistor.
- the gate of the field effect transistor is coupled to the output terminal of the power supply module through the corresponding first switch, the drain of the field effect transistor is coupled to the power supply terminal through the load impedance, and the source of the field effect transistor is coupled to the ground terminal.
- the power subunit includes multiple power transistors, multiple first switches, and load impedances, and the multiple power transistors correspond to the multiple first switches one by one.
- the control pole of the power transistor is coupled to the output terminal of the power supply module through the corresponding first switch, the first pole of the power transistor is coupled to the power supply terminal through the load impedance, and the second pole of the power transistor is coupled to the ground terminal.
- the power transistor may be a triode.
- the base of the triode is coupled to the output terminal of the power supply module through the corresponding first switch, the collector of the triode is coupled to the power supply terminal through the load impedance, and the emitter of the triode is coupled to the ground terminal.
- the power transistor may be a field effect transistor.
- the gate of the field effect transistor is coupled to the output terminal of the power supply module through the corresponding first switch, the drain of the field effect transistor is coupled to the power supply terminal through the load impedance, and the source of the field effect transistor is coupled to the ground terminal.
- the power subunit includes multiple power transistors, multiple second switches, and load impedances, and the multiple power transistors correspond to the multiple second switches one by one.
- the control pole of the power tube is coupled to the output terminal of the power supply module, the first stage of the power tube is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the second pole of the power tube is coupled to the ground terminal.
- the power transistor may be a triode.
- the base of the triode is coupled to the output terminal of the power supply module, the collector of the triode is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the emitter of the triode is coupled to the ground terminal.
- the power transistor may be a field effect transistor.
- the gate of the field effect transistor is coupled to the output terminal of the power supply module, the drain of the field effect transistor is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the source of the field effect transistor is coupled to the ground terminal.
- the power subunit includes a plurality of power transistors, a plurality of first switches, a plurality of second switches, and a load impedance, and the plurality of power transistors, the plurality of first switches, and the plurality of second switches One to one correspondence.
- the control pole of the power transistor is coupled to the output terminal of the power supply module through the corresponding first switch, the first stage of the power transistor is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the second pole of the power transistor is coupled to the ground terminal.
- the power transistor may be a triode.
- the base of the triode is coupled to the output terminal of the power supply module through the corresponding first switch, the collector of the triode is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the emitter of the triode is coupled to the ground terminal .
- the power transistor may be a field effect transistor.
- the gate of the FET is coupled to the output terminal of the power supply module through the corresponding first switch, the drain of the FET is coupled to the power supply terminal through the load impedance and the corresponding second switch, and the source of the FET is coupled to the ground terminal .
- the power subunit in the embodiment of the present application is not limited to the above four possible implementations (that is, the power subunit is not limited to the above four topological structures), and the power subunit can also be implemented through other topological structures based on
- the control of the power supply current to the static working current of the power module is not limited in this embodiment of the present application.
- the power subunit further includes a DC blocking capacitor and a bias inductor
- the DC blocking capacitor is arranged between the control electrode of the power transistor and the connection signal source, and the bias inductor is arranged between the control electrode of the power transistor and the bias unit of the power supply module.
- the power sub-unit further includes multiple DC blocking capacitors and multiple bias inductors, and the multiple DC blocking capacitors, multiple bias inductors and multiple power transistors correspond one-to-one;
- One end of the DC blocking capacitor is coupled to the signal source, the other end of the DC blocking capacitor is coupled to the control pole of the power tube, one end of the bias inductor is coupled to the bias unit of the power supply module, and the other end of the bias inductor is coupled to the control pole of the power tube coupling.
- the above-mentioned DC blocking capacitor plays the role of isolating the DC signal through the AC signal
- the above-mentioned bias inductance plays the role of isolating the high-frequency signal through the low-frequency signal, and can transfer the modulated signal from the signal source (it can be a single tone signal, or It can be a high-frequency AC signal, such as a high-frequency amplitude signal, a high-frequency phase signal, etc.) and a low-frequency voltage signal from the bias unit input to the power module, which improves the signal input to the power module (including modulation from the signal source) signal and the quality of the low frequency voltage signal from the bias unit).
- the power module may be a power amplifier PA, configured to work in a transmission time slot in a time division duplex TDD mode.
- the power module may be a low noise amplifier LNA, configured to work in a receiving time slot in a time division duplex TDD mode.
- LNA low noise amplifier
- the embodiment of the present application also provides an electronic device, which may include multiple power circuits in the above-mentioned first aspect and possible implementations thereof, or may include multiple power circuits in the above-mentioned second aspect and possible implementations thereof power circuit. Multiple power circuits are coupled in series or in parallel.
- the electronic device provided in the embodiment of the present application may further include a circuit board; the power circuit is disposed on the circuit board.
- FIG. 1 provides a schematic structural diagram of a power circuit A of an embodiment of the present application
- FIG. 2 provides a schematic structural diagram of the power supply module A2 of the embodiment of the present application
- FIG. 3 provides a schematic structural diagram of the current source unit A21 of the embodiment of the present application.
- FIG. 4 provides a schematic diagram of a driver response delay unit according to an embodiment of the present application
- FIG. 5 provides a timing diagram of an embodiment of the present application
- FIG. 6 provides a schematic structural diagram of the current source unit A21 of the embodiment of the present application.
- FIG. 7 provides a schematic structural diagram of the current source unit A21 of the embodiment of the present application.
- FIG. 8 provides a schematic structural diagram of the bias unit A23 of the embodiment of the present application.
- FIG. 9 provides a schematic structural diagram of the power supply module A2 of the embodiment of the present application.
- FIG. 10 provides a schematic structural diagram of the voltage source unit A22 of the embodiment of the present application.
- FIG. 11 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 12 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 13 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 14 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 15 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 16 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 17 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 18 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 19 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 20 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 21 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 22 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 23 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 24 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- FIG. 25 provides a schematic structural diagram of the power module A1 of the embodiment of the present application.
- Fig. 26 provides a schematic structural diagram of the power circuit A of the embodiment of the present application.
- FIG. 27 provides a schematic structural diagram of the power circuit A of the embodiment of the present application.
- FIG. 28 provides a schematic structural diagram of the power circuit A of the embodiment of the present application.
- FIG. 29 provides a schematic structural diagram of an electronic device EE according to an embodiment of the present application.
- FIG. 30 provides a schematic structural diagram of an electronic device EE according to an embodiment of the present application.
- FIG. 31 provides a timing diagram of an embodiment of the present application.
- FIG. 32 provides a schematic structural diagram of an electronic device EE according to an embodiment of the present application.
- FIG. 33 provides a schematic structural diagram of an electronic device EE according to an embodiment of the present application.
- FIG. 34 provides a schematic structural diagram of an electronic device EE according to an embodiment of the present application.
- At least one (item) means one or more, and “multiple” means two or more.
- “And/or” is used to describe the association relationship of associated objects, indicating that there can be three types of relationships, for example, “A and/or B” can mean: only A exists, only B exists, and A and B exist at the same time , where A and B can be singular or plural.
- the character “/” generally indicates that the contextual objects are an “or” relationship.
- At least one of the following” or similar expressions refer to any combination of these items, including any combination of single or plural items.
- At least one item (piece) of a, b or c can mean: a, b, c, "a and b", “a and c", “b and c", or "a and b and c ", where a, b, c can be single or multiple.
- Power circuits such as power amplifier circuits or digital-to-analog conversion circuits, etc.
- the instantaneous current The more severe the mutation, the greater the voltage fluctuation caused on the power supply.
- the voltage fluctuation on the power supply will not only affect the performance of the unclosed power circuit, but also accelerate the aging of the components (such as power tubes) in the power circuit when the voltage fluctuation exceeds a certain voltage range, affecting the reliability of the power circuit and longevity.
- the embodiment of the present application adopts the following two approaches:
- Approach 1 Increase the capacitance of the decoupling capacitor without increasing the number of decoupling capacitors in the power supply, or increase the number of decoupling capacitors without increasing the capacitance of the decoupling capacitor.
- Either increasing the capacitance of the decoupling capacitor or increasing the number of decoupling capacitors can reduce the inductance of the equivalent inductance in the power supply.
- the inductance L of the inductance is proportional to the voltage v of the power supply, that is to say, the voltage v will decrease with the inductance L of the inductance And reduce.
- a different independent power supply such as a low dropout regulator (LDO) or a DC converter (ie, a DC-DC converter) is used to power the power circuit. That is to say, the modules that are susceptible to interference and the modules that will generate large disturbances in the power circuit are powered separately through different independent power supplies.
- LDO low dropout regulator
- DC converter ie, a DC-DC converter
- the embodiment of the present application also provides a power circuit, which can make the voltage of the power supply (determined by the quiescent operating current below, proportional to the quiescent operating current) during the power circuit opening or closing process
- the slow change in that is, the voltage of the power supply can be slowly increased when the power circuit is turned on, and the voltage of the power supply can be slowly decreased when the power circuit is turned off), thereby reducing the impact of the power circuit on the power supply , realizing the effective control of the voltage fluctuation on the power supply, and improving the stability of the power supply.
- the power circuit provided in this application may be a power amplifier circuit or a digital-to-analog conversion circuit, etc., which can slowly increase or decrease the voltage of the power supply during the process of turning on or off the power circuit.
- the specific form of the circuit is not limited.
- the power circuit provided by the embodiment of the present application will be introduced by taking the slow increase of the current of the power supply when the power circuit is turned on as an example.
- the power circuit A may include a power module A1 and a power supply module A2 coupled to the power module A1 .
- the power module A1 is configured to supply power in a time-sharing power-on manner.
- the power module A1 supplies power in a time-division power-on manner, which may include but not limited to the following two situations:
- Case 1 The power supply module A2 supplies power to the power module A1 in a time-sharing power-on manner.
- the power supply module A2 supplies power to the power module A1 in a time-sharing power-on manner
- the power supply module A2 may provide power supply current for the power module A1 in a time-sharing power-on manner (which may be represented by Ib1 or called is the bias current) or the supply voltage (which can be represented by V bias , and can also be called the bias voltage).
- the supply current Ib1 may indicate the output current of the power supply module A1
- the supply voltage V bias may indicate the output voltage of the power supply module A2.
- the power supply module A2 is configured to: provide the power module A1 with the power supply current I b1 or the power supply voltage V bias in a time-sharing power-on manner, and the power module A1 is configured to: based on the power supply provided by the power supply module A2
- the current I b1 or the supply voltage V bias realizes power-on. That is to say, the power module A1 controls the quiescent working current of the power module A1 based on the supply current I b1 or the supply voltage V bias (which may be represented by I amp , and may also be called a mirror current).
- the power supply of the power supply module A2 can be that the power supply module A2 provides the power supply current I b1 for the power module A1 (see the introduction above for the supply current), and it can also be that the power supply module A2 provides the power supply voltage V bias for the power module A1 (power supply Voltage can be found in the introduction above).
- the power module A1 is powered on in a time-sharing manner. That is to say, the power module A1 controls the static working current I amp of the power module A1 based on the supply current I b1 or the supply voltage V bias provided by the power supply module.
- the power supply module A2 may include multiple power supply subunits A20. A plurality of power supply sub-units A20 are coupled to the power supply module A2.
- multiple power supply sub-units A20 may be coupled with respective control signal lines, and delay units are coupled between the multiple power supply sub-units A20.
- the control signal line is used to control the power supply module A2 to supply power to the power module A1 in a time-sharing power-on manner according to the time delay set by the delay unit.
- the multiple power supply sub-units A20 may respectively include respective control signal lines for controlling the power supply module A2 to supply power to the power module A1.
- the power circuit provided by the embodiment of the present application does not increase the off-chip devices (such as the decoupling capacitor in mode 1, or the independent power supply in mode 2), and supplies power through the power module in a time-sharing power-on mode, so that the power supply
- the voltage of the power circuit increases slowly during the opening process of the power circuit, thereby reducing the impact of the power module (or power circuit) on the power supply at the moment of opening, and improving the stability of the power supply.
- the time-sharing power-on method improves the reliability of the power circuit, reduces the size of the power circuit, and reduces the cost of the power circuit.
- the power circuit provided by the embodiment of the present application can also stop the power supply through the power module in a time-sharing manner, so that the voltage of the power supply decreases slowly during the shutdown process of the power circuit, thereby reducing the power module (also can be said It is the power circuit)
- the impact of the power module on the power supply at the moment of shutdown improves the stability of the power supply.
- the time-sharing power-off method can also improve the reliability of the power circuit, reduce the size of the power circuit, and reduce the cost of the power circuit.
- the power supply unit A20 may include a current source unit A21, and the current source unit A21 is coupled to the power module A1, as shown in FIG. 2 .
- the current source unit A21 can supply power to the power module A1 through the following two structures, that is, the current source unit A21 can provide the power supply current I b1 for the power module A1 through the following two structures:
- the current source unit A21 may include N current sources (ie, current source IS1, current source IS2, current source IS3, ..., current source ISN) and N switches (ie, switch S11, switch S12, switch S13, . . . , switch S1N).
- the N switches are configured to: control N current sources to supply power to the power module A1 based on the control signals provided by the control signal lines, that is, the N switches control the N current sources to supply power to the power module A1 based on the control signals provided by the control signal lines Provide supply current I b1 .
- the current source IS1, the current source IS2, the current source IS3, ..., the current source ISN do not have the timing control function, that is, the current source IS1, the current source IS2, the current source IS3, ..., the current source ISN It has no control function for the generation time, stabilization time, stop time and the relationship between each other of its own output current. Therefore, it is necessary to provide switch S11 , switch S12 , switch S13 , . . . , switch S1N.
- the current source IS1, the current source IS2, the current source IS3, ..., the current source ISN are coupled with the switch S11, the switch S12, the switch S13, ..., the switch S1N one by one, for example, the current source IS1 is coupled with the switch S11, The current source IS2 is correspondingly coupled to the switch S12, and so on, the current source ISN is correspondingly coupled to the switch S1N.
- current source IS1, current source IS2, current source IS3, ..., current source ISN generate output currents of multiple current sources, as shown in FIG. 3, current source IS1 generates output current IS1 of current source IS1 , and current source IS2 The current source IS2 generates the output current I S2 , the current source IS3 generates the current source IS1 output current I S3 , and so on, the current source ISN generates the output current I SN of the current source ISN.
- the current source IS1, the current source IS2, the current source IS3, ..., the current source ISN do not have the sequence control function, so in the power circuit (here can be all devices in the power circuit, such as the delay unit in the power circuit, drive unit, current source unit, etc.) receive control signals such as time division duplex (time division dual, TDD) signals, etc., can pass through the N drivers of the power circuit (ie, the driver D1 in Figure 4, the driver D2, the driver D3, ..., the driver DN have a total of N drivers, and the N drivers are coupled with the N switches one by one), and the N switches are respectively driven according to the delay interval ( ⁇ in Figure 4) set by the delay unit (such as the driver D1 drives The switch S11, the driver D2 drives the switch S12, etc.), so that the switch S11, the switch S12, the switch S13, ..., the switch S1N are sequentially closed according to the delay interval, and then the power supply current Ib1 is slowly increased.
- TDD time division dual
- the current source IS1 After the current source IS1 to the current source ISN in Fig. 3 and the driver D1 to the driver DN in Fig. 4 all receive the time division duplex TDD signal, the current source IS1 generates the output current I S1 of the current source IS1, At the same time, the driver D1 directly (that is, without a delay interval) drives the switch S11 to close the switch S11.
- I b1 I S1 is satisfied; the premise that the current source IS1 generates the output current I S1 of the current source IS1 and the switch S11 is closed Next, the current source IS2 generates the output current I S2 of the current source IS2, and at the same time, the driver D2 drives the switch S12 after a delay interval ⁇ , so that the switch S12 is closed.
- the switches S1N are closed sequentially, and the supply current I b1 provided by the power supply module A2 increases slowly from I S1 to I S1 +I S2 +I S3 +...+I SN , that is, the supply current I b1 of the power supply module increases slowly, thereby realizing
- the power supply voltage V bias of the power supply module is slowly increased, and the static operating current I amp of the power module is slowly increased through the power module, reducing the impact of the power module on the power supply and improving the stability of the power supply.
- the current source unit A21 may include a current source IS1 .
- the current source IS1 is configured to supply power to the power module A1 in a time-sharing power-on manner, that is, the current source IS1 provides a power supply current I b1 to the power module A1 in a time-sharing power-on manner.
- the current source IS1 has a timing control function, that is to say, the current source IS1 has a control function on the generation time, stabilization time, stop time and the relationship among them of its own output current. It can be understood that since the current source IS1 has a timing control function, there is no need to set a switch in Structure 1-2. Then, the current source IS1 can output a slowly increasing supply current I b1 through the timing control function.
- the above-mentioned power supply module A2 may further include a bias unit A23. As shown in FIG. The output terminal of is coupled with the input terminal of the power module A1.
- the current source unit A21 is further configured to provide a supply current I b1 for the bias unit, and the bias unit A23 is configured to provide a supply voltage V bias for the power module A1 based on the supply current I b1 .
- the bias unit A23 may be any one of a triode, a field effect transistor (which may be an NMOS transistor (N-metal-oxide-semiconductor)) or an IGBT (insulated gate bipolar transistor, that is, an insulated gate bipolar transistor) .
- a field effect transistor which may be an NMOS transistor (N-metal-oxide-semiconductor)
- IGBT insulated gate bipolar transistor, that is, an insulated gate bipolar transistor
- the bias unit A23 may include an NMOS transistor.
- the source s of the NMOS transistor is coupled to -VDD, and the drain d of the NMOS transistor is coupled to the output terminal of the current source unit A21 (refer to the introduction above, the drain d of the NMOS transistor can be connected to the N in the current source unit of structure 1
- the switch coupling may also be coupled with the current source IS1 of the current source unit of structure 1-2).
- the gate g of the NMOS transistor is coupled to the drain d, and the gate g of the NMOS transistor is coupled to the input terminal of the power module A1 (see the introduction below, the gate g of the NMOS transistor can be connected with the power by the bias inductor in the power module A1
- the power tube coupling in the module A1 can also be directly coupled with the power tube in the power module A1.
- the grid g of the NMOS tube in the bias unit A23 directly or through the bias An inductor, a resistor, etc. are coupled to the gate g of the NMOS transistor in the power module A1).
- the above-mentioned power supply subunit A20 may include a voltage source unit A22, and the voltage source unit A22 is coupled to the power module A1, as shown in FIG. 9 .
- the current source unit A21 can provide the power supply voltage V bias for the power module A1 through the structure shown in FIG. 10 .
- the voltage source unit A22 includes a voltage source VS1.
- the voltage source VS1 is configured to: supply power to the power module A1 based on the control signal provided by the control signal line, that is, the voltage source VS1 provides the power module A1 with a power supply voltage V bias based on the control signal provided by the control signal line.
- the voltage source VS1 has a timing control function, that is to say, the voltage source VS1 has a control function on the generation time, stabilization time, stop time and the relationship between the output voltages of the voltage source VS1. It can be understood that since the voltage source VS1 has a timing control function, there is no need to set a switch in structure 2-1. Then, the voltage source VS1 can output the slowly increasing supply voltage V bias through the timing control function.
- the power module A1 may include a plurality of power subunits A10; the power supply module A2 is used to supply power to the plurality of power subunits A10 in a time-sharing manner.
- the power subunit A10 may include a power transistor M1 and a load impedance ZL, as shown in FIG. 11 .
- the control pole F0 of the power transistor M1 is coupled to the output terminal of the bias unit A23
- the first pole F1 of the power transistor M1 is coupled to the power supply terminal V through the load impedance ZL
- the second pole F2 of the power transistor M1 is coupled to the ground terminal E coupling.
- the power transistor M1 may be a triode or a field effect transistor (FET (field effect transistor, may be a junction field effect transistor JFET (junction field effect transistor), or may be an insulated gate field effect transistor (also called a MOS transistor))
- FET field effect transistor
- JFET junction field effect transistor
- MOS transistor insulated gate field effect transistor
- the power tube M1 can also be an IGBT (compounded by an insulated gate field effect transistor IGFET (insulated gate field effect transistor) and a triode T (transistor)).
- the power transistor M1 is a triode, as shown in Figure 12, the base b (i.e. the control electrode) of the triode T is coupled to the output terminal of the bias unit A23, and the collector c (i.e. the first pole) of the triode T passes through the load impedance ZL is coupled with +VCC (that is, the power supply terminal), and the emitter e of the triode T (that is, the second stage) is coupled with -VCC (that is, the ground terminal, or GND).
- OUT in FIG. 12 represents the output terminal of the power subunit A10
- I amp represents the supply current of the power subunit A10.
- the power subunit A10 may further include a DC blocking capacitor C and a bias inductor L.
- one end of the DC blocking capacitor C is coupled to the connected signal source IN
- the other end of the DC blocking capacitor C is coupled to the base b of the transistor T
- one end of the bias inductor L is coupled to the bias unit A23
- the bias inductor L The other end is coupled with the base b of the transistor T.
- the modulation from the signal source IN can be The signal (which can be a single tone signal or a high-frequency AC signal, such as a high-frequency amplitude signal, a high-frequency phase signal, etc.) and a low-frequency voltage signal from the bias unit A23 are input into the power subunit A10.
- the power transistor M1 is an NMOS transistor (the embodiment of the present application takes an NMOS transistor as an example), as shown in FIG.
- the drain d (that is, the first pole) is coupled with +VDD (that is, the power supply terminal) through the load impedance ZL, and the source s (that is, the second stage) of the NMOS transistor is coupled with -VDD (that is, the ground terminal, or GND) .
- the power sub-unit A10 may also include a DC blocking capacitor C (same function as the above DC blocking capacitor C) and a bias inductor L (similar to the above DC blocking capacitor C Straight capacitor C has the same effect).
- a DC blocking capacitor C (same function as the above DC blocking capacitor C)
- a bias inductor L (similar to the above DC blocking capacitor C Straight capacitor C has the same effect).
- one end of the DC blocking capacitor C is coupled to the signal source IN, and the other end of the DC blocking capacitor C is coupled to the gate g of the NMOS transistor.
- One end of the bias inductor L is coupled to the bias unit A23, and the other end of the bias inductor L is coupled to the gate g of the NMOS transistor.
- the power subunit A10 may include H power transistors, H switches (that is, H first switches) and a load impedance (the load impedance may be one or multiple).
- the H power transistors are coupled to the H switches in one-to-one correspondence.
- each of the H power transistors can be a triode or a field effect transistor FET (it can be a junction field effect transistor JFET, or an insulated gate field effect transistor (also called a MOS transistor)), and the H power transistors can also be all It is an IGBT (a combination of an insulated gate field effect transistor IGFET and a triode).
- a field effect transistor FET it can be a junction field effect transistor JFET, or an insulated gate field effect transistor (also called a MOS transistor)
- IGBT a combination of an insulated gate field effect transistor IGFET and a triode
- the H power tubes are triodes.
- the power sub-unit A10 includes H transistors, H first switches (that is, switch S21, switch S22, . . . , switch S2H in FIG. 16 ) and a load impedance.
- this application introduces a power subunit A10 by taking a load impedance ZL as an example. Only the triode T11 is marked in FIG. 16 , and IM11 , IM12 , . . . , IM1H in FIG. 16 are integrated components integrating corresponding triodes.
- the base b (i.e. the control electrode) of the triode T11 is coupled to the output terminal of the bias unit A23 through the switch S21 (referring to Fig. 8, the base b of the triode T11 can be connected to the NMOS transistor in the bias unit A23 through the switch S21
- the grid g (which can be considered as the output terminal of the bias unit A23) is coupled)
- the collector c (ie, the first pole) of the transistor T11 is coupled with +VCC (ie, the power supply terminal V) through the load impedance ZL
- the pole e (that is, the second stage) is coupled with -VCC (that is, the ground terminal E, which can be GND).
- the power sub-unit A10 may also include H DC blocking capacitors C (same function as the DC blocking capacitor C introduced above) and H bias inductors L (same function as the DC blocking capacitor C introduced above) ). It should be noted that only the DC blocking capacitor C11 and the bias inductor L11 coupled to the base b of the transistor T11 are marked in FIG. 17 .
- one end of the DC blocking capacitor C11 is coupled to the connection signal source IN, the other end of the DC blocking capacitor C11 is coupled to the base b of the transistor T11, one end of the bias inductor L11 is coupled to the bias unit A23, and the bias inductor L11
- the other end of the transistor T11 is coupled with the base b of the transistor T11, and the DC blocking capacitor C11, the bias inductor L11 and the transistor T11 are integrated on the integrated component IM11. It should be noted that the coupling relationship between the triode integrated on the integrated components IM12, ..., IM1H in Fig.
- the H power transistors are all NMOS transistors. That is to say, the power subunit A10 may include H NMOS transistors, H first switches (that is, switch S21 , switch S22 , . . . , switch S2H in FIG. 18 ) and a load impedance ZL.
- this application uses a load impedance ZL as an example to introduce the power sub-unit A10 .
- the gate g (i.e. the control electrode) of NMOS11 is coupled with the output end of bias unit A23 through switch S21 (referring to Fig. 8, the gate g of NMOS11 can be connected with the gate of NMOS transistor in bias unit A23 through switch S21 Pole g (which can be considered as the output terminal of the bias unit A23) is coupled), the drain d of NMOS11 (that is, the first pole) is coupled with +VDD (that is, the power supply terminal V) through the load impedance ZL, and the source of NMOS11 s (that is, The second stage) is coupled with -VDD (that is, the ground terminal E, which can also be GND).
- OUT in FIG. 18 also represents the output terminal of the power subunit A10, and I amp also represents the supply current of the power subunit A10.
- the power sub-unit A10 may also include H DC blocking capacitors C (same function as the DC blocking capacitor C introduced above) and H bias inductors L (same function as the DC blocking capacitor C introduced above) ). It should be noted that only the DC blocking capacitor C11 and the bias inductor L11 coupled to the gate g of the NMOS 11 are marked in FIG. 19 .
- one end of the DC blocking capacitor C11 is coupled to the signal source IN, the other end of the DC blocking capacitor C11 is coupled to the gate g of the NMOS11, and one end of the bias inductor L11 is coupled to the bias unit A23 (refer to FIG. 8, the bias One end of the inductor L11 can be coupled with the gate g of the NMOS transistor in the bias unit A23 (which can be considered as the output terminal of the bias unit A23), the other end of the bias inductor L11 is coupled with the gate g of the NMOS11, and the DC blocking capacitor C11, bias inductor L11 and NMOS11 are integrated on the integrated component IM11.
- OUT in FIG. 19 also represents the output terminal of the power subunit A10, and I amp also represents the supply current of the power subunit A10.
- the power sub-unit A10 may include K power transistors, K switches (that is, K second switches) and load impedances (the load impedance may be one or multiple, and the implementation of this application Take K load impedances as an example), K power transistors are coupled with K switches and K load impedances one by one.
- the K power tubes can all be triodes or field effect transistors FET (which can be junction field effect transistors JFETs, or insulated gate field effect transistors (also called MOS tubes)), and the K power tubes can also be All are IGBTs (compounded by insulated gate field effect transistors IGFETs and triodes).
- FET field effect transistors
- IGFET insulated gate field effect transistors
- the K power tubes are triodes. That is to say, the K power transistors include K transistors, K second switches (that is, switches S31 , switches S32 , . . . , switches S3K in FIG. 20 ) and H load impedances.
- triode T11 and the load impedance ZL1 are marked in FIG. 20 , and IM11 , IM12 , . . . , IM1K are integrated components integrating the corresponding triodes.
- the base b (i.e., the control electrode) of the transistor T11 is coupled to the output terminal of the bias unit A23 (referring to FIG. 8, the base b of the transistor T11 can be connected to the gate g of the NMOS transistor in the bias unit A23 (which can It is considered that the output end of the bias unit A23) is coupled), the collector c (ie, the first pole) of the triode T11 is coupled with +VCC (ie, the power supply terminal V) through the load impedance ZL1 and the switch S31, and the emitter e of the triode T11 ( That is, the second stage) is coupled with -VCC (that is, the ground terminal E, which can be GND).
- +VCC ie, the power supply terminal V
- OUT in FIG. 20 also represents the output terminal of the power subunit A10, and I amp also represents the supply current of the power subunit A10.
- the power sub-unit A10 may also include K DC blocking capacitors and K bias inductors. It should be noted that only the DC blocking capacitor C21 coupled with the base b of the transistor T11 and the bias inductors are marked in FIG. Inductor L21.
- one end of the DC blocking capacitor C21 is coupled to the signal source IN, the other end of the DC blocking capacitor C21 is coupled to the base b of the transistor T11, and one end of the bias inductor L21 is coupled to the bias unit A23 (refer to FIG. 8, bias One end of the inductance L11 can be coupled with the gate g of the NMOS transistor in the bias unit A23 (which can be considered as the output end of the bias unit A23), and the other end of the bias inductance L21 is coupled with the base b of the transistor T11.
- the direct capacitor C21, the bias inductor L21 and the transistor T11 are integrated on the integrated component IM11.
- the K power transistors are all NMOS transistors. That is to say, the power subunit A10 includes K NMOS transistors, K second switches (ie, switch S31 , switch S32 , . . . , switch S3K in FIG. 22 ) and K load impedances.
- NMOS11 and load impedance ZL1 are marked in FIG. 22 , and IM11 , IM12 , . . . , IM1K are integrated components integrating corresponding triodes.
- the gate g (i.e., the control electrode) of NMOS11 is coupled to the output terminal of bias unit A23 (referring to FIG.
- the output terminal of the bias unit A23) is coupled)
- the drain d (ie the first pole) of the NMOS11 is coupled with +VDD (ie the power supply terminal V) through the load impedance ZL1 and the switch S31
- the source s of the NMOS11 (ie the second stage ) is coupled with -VDD (that is, the ground terminal E, which may be GND).
- OUT in FIG. 22 also represents the output terminal of the power subunit A10, and I amp also represents the supply current of the power subunit A10.
- the power subunit A10 may also include K DC blocking capacitors and K bias inductors. It should be noted that only the DC blocking capacitor C21 and the bias inductor coupled to the gate g of the NMOS 11 are marked in FIG. 23 L21.
- one end of the DC blocking capacitor C21 is coupled to the signal source IN, the other end of the DC blocking capacitor C21 is coupled to the gate g of the NMOS11, and one end of the bias inductor L21 is coupled to the bias unit A23 (refer to FIG. 8, the bias One end of the inductor L21 can be coupled to the gate g of the NMOS transistor in the bias unit A23 (which can be considered as the output terminal of the bias unit A23), the other end of the bias inductor L21 is coupled to the gate g of the NMOS11, and the DC blocking capacitor C21, bias inductor L21 and NMOS11 are integrated on the integrated component IM11.
- OUT in FIG. 23 also represents the output terminal of the power subunit A10, and I amp also represents the supply current of the power subunit A10.
- the power subunit A10 may include P power transistors, P first switches, P second switches, and load impedances (the load impedance may be one or more, and the embodiment of the present application uses multiple load impedances (that is, P load impedances) as an example).
- the P power transistors are coupled to the P first switches, the P second switches, and the P load impedances in one-to-one correspondence.
- the P power transistors are all NMOS transistors. That is to say, the power subunit A10 includes P NMOS transistors, P first switches (that is, switch S21, switch S22, ..., switch S2P in FIG. 24 ), P second switches (that is, switch S31 in FIG. 24 , switch S32, . . . , switch S3K) and P load impedances.
- NMOS11 and load impedance ZL1 are marked in FIG. 24 , and IM11 , IM12 , .
- the gate g (i.e. the control electrode) of NMOS11 is coupled to the output terminal of bias unit A23 through switch S21 (refer to Figure 8, the gate g of NMOS11 can be connected to the NMOS transistor in bias unit A23 through switch S21
- the gate g of the bias unit A23 (can be considered as the output terminal of the bias unit A23) is coupled)
- the drain d of the NMOS11 (that is, the first pole) is coupled with +VDD (that is, the power supply terminal V) through the load impedance ZL and the switch S31
- the source s (that is, the second stage) is coupled to -VDD (that is, the ground terminal E, which can also be GND).
- OUT in FIG. 24 also represents the output terminal of the power subunit A10, and I amp also represents the supply current of the power subunit A10.
- the power subunit A10 may also include P DC blocking capacitors and P bias inductors. It should be noted that only the DC blocking capacitor C31 and the bias inductor coupled to the gate g of the NMOS11 are marked in FIG. 25 L31.
- one end of the DC blocking capacitor C31 is coupled to the signal source IN, the other end of the DC blocking capacitor C31 is coupled to the gate g of the NMOS11, and one end of the bias inductor L31 is coupled to the bias unit A23 (refer to FIG. 8, the bias One end of the inductor L31 can be coupled to the gate g of the NMOS transistor in the bias unit A23 (which can be considered as the output terminal of the bias unit A23), the other end of the bias inductor L31 is coupled to the gate g of the NMOS11, and the DC blocking capacitor C31, bias inductor L31 and NMOS11 are integrated on the integrated component IM11.
- the coupling relationship between the NMOS transistors integrated on the integrated component IM12 to the integrated component IM1P, the corresponding DC blocking capacitors, and the corresponding bias inductors is similar to the coupling relationship between NMOS11, the DC blocking capacitor C31, and the bias inductor L31.
- the application examples are not described in detail.
- the current source unit, the bias unit and the power module can be combined to obtain the current signal for modulating the current signal. power circuit.
- the power circuit A shown in FIG. 26 can be obtained by combining FIG. 3 , FIG. 8 and FIG. 15 .
- N current sources i.e., current source IS1, current source IS2, current source IS3, ..., current source ISN
- the switches ie, switch S11 , switch S12 , switch S13 , . . . , switch S1N
- the NMOS in the bias unit A23 outputs a slowly increasing supply voltage V bias according to the slowly increasing supply current I b1 .
- the NMOS in the power subunit A10 controls the static operating current I amp of the power subunit A10 to gradually increase according to the slowly increasing supply voltage V bias , avoiding the power circuit from being turned on
- the impact of the instantaneous power circuit on the power supply reduces the fluctuation of the power supply voltage +VDD and improves the stability of the power supply.
- the reliability of the power circuit is improved, the size of the power circuit is reduced, and the cost of the power circuit is reduced.
- the power circuit A shown in FIG. 27 can be obtained by combining FIG. 6 , FIG. 8 and FIG. 19 .
- the slowly increasing supply current I b1 can be obtained through a current source (ie, current source IS1 ) in the current source unit A21 (take the electronics unit A20 including a current source unit A21 as an example).
- the NMOS in the bias unit A23 outputs a slowly increasing supply voltage V bias according to the increasing supply current I b1 .
- the power subunit A10 (taking the power module A1 including one power subunit A10 as an example) integrates the NMOS (such as NMOS11) on the integrated component IM11 to the integrated component IM1H to control the static operating current I amp to gradually increase according to the slowly increasing supply voltage V bias Large, avoiding the impact of the power module on the power supply when the power circuit is turned on, thereby reducing the fluctuation of the power supply voltage +VDD and improving the stability of the power supply. At the same time, the reliability of the power circuit is improved, the size of the power circuit is reduced, and the cost of the power circuit is reduced.
- NMOS such as NMOS11
- the power circuit A shown in FIG. 28 can be obtained by combining FIG. 6 , FIG. 8 and FIG. 23 .
- the slowly increasing supply current I b1 can be obtained through a current source (ie, current source IS1 ) in the current source unit A21 (take the electronics unit A20 including a current source unit A21 as an example).
- the NMOS in the bias unit A23 outputs a slowly increasing supply voltage V bias according to the increasing supply current I b1 .
- power subunit A10 Based on the slowly increasing supply voltage V bias , power subunit A10 (taking power module A1 including one power subunit A10 as an example) integrates NMOS (such as NMOS11) on integrated module IM11 to integrated module IM1H and power subunit A10
- NMOS such as NMOS11
- the switches S31 to S3K control the static operating current I amp to gradually increase, avoiding the impact of the power module on the power supply at the moment when the power circuit is turned on, thereby reducing the fluctuation of the power supply +VDD and improving the stability of the power supply.
- the power circuit shown in FIG. 28 has the same function as the power circuit shown in FIG. 27 , and both have the advantages of high reliability, small size and low cost.
- power circuits of other structural forms can also be obtained by combining FIG. 3 , FIG. 8 and FIG. 19 or combining FIG. 3 , FIG. 8 and FIG. 23 .
- the embodiment of the present application does not limit the structural form of the power circuit.
- the voltage source unit such as the voltage source shown in Figure 10
- the power module as shown in Figure 11 to Figure 25 Any one of the power modules is combined to obtain a power circuit.
- the embodiment of the present application further provides an electronic device EE (which may be called a multi-stage power circuit), as shown in FIG. 29 .
- the electronic equipment EE includes R power circuits (ie, power circuits AMP1, power circuits AMP2, ..., power circuits AMPR in FIG. 29), and the R power circuits are connected in series, that is, the R power circuits pass through the stage Linked coupling.
- the electronic equipment EE includes three power circuits including a power circuit AMP1, a power circuit AMP2, and a power circuit AMP3. coupling.
- the power circuit AMP1 includes a power module A11 (refer to the introduction about the power subunit A10 above), and a current source unit that provides supply current for the power module A11 (not shown in FIG. Introduction of A21) and a bias unit that outputs the supply voltage V bias1 based on the supply current (not shown in FIG. 30 , please refer to the introduction about the bias unit A23 above).
- the power circuit AMP2 includes a power module A12 (refer to the introduction about the power subunit A10 above), and a current source unit that provides supply current for the power module A12 (not shown in FIG. ) and a bias unit that outputs the supply voltage V bias2 based on the supply current (not shown in FIG. 30 , please refer to the introduction about the bias unit A23 above).
- the power circuit AMP3 includes a power module A13 (refer to the introduction about the power subunit A10 above), and a current source unit that provides power supply current for the power module A13 (not shown in FIG. 30 , You can refer to the above introduction about the bias unit A23) and the bias unit that outputs the supply voltage V bias3 based on the supply current (not shown in FIG. 30 , you can refer to the above introduction about the bias unit A23).
- the power modules A11 to A13 all include power transistors (taking NMOS transistors as an example). It can be understood that the drain of the NMOS transistor of the power module A11, the drain of the NMOS transistor of the power module A12, and the drain of the NMOS transistor of the power module A13 can be coupled with the same +VDD (such as the power supply terminal V in FIG. 30 ), They can also be coupled to their corresponding +VDD respectively.
- the source of the NMOS transistor of the power module A11, the source of the NMOS transistor of the power module A12, and the source of the NMOS transistor of the power module A13 are respectively connected to the corresponding ground terminals (such as the ground terminal E1, the ground terminal E2, and the ground terminal in Figure 30). ground terminal E3).
- the slowly increasing quiescent working current of the power module A11 can be obtained through the current source unit of the power circuit AMP1 in FIG. 30 .
- a slowly increasing supply voltage V bias1 is obtained through the bias unit of the power circuit AMP1 in FIG. 30 .
- the slowly increasing supply voltage V bias2 can be obtained through the current source unit and bias unit of the power circuit AMP2 in Figure 30, and can also be slowly increased through the current source unit and bias unit of the power circuit AMP3 in Figure 30 supply voltage V bias3 .
- the delay interval that can be set by the delay unit is between the power circuit AMP1 and the power circuit AMP2 And between the power circuit AMP2 and the power circuit AMP3 (that is, between the stages) to set the delay interval (that is, in the timing diagram of the TDD signal, the power supply voltage V bias1 , the power supply voltage V bias2 , and the power supply voltage V bias3 shown in FIG.
- the delay interval between the power supply voltage V bias1 and the power supply voltage V bias2 and the delay interval between the power supply voltage V bias2 and the power supply voltage V bias3 can be different), further reducing the impact of the electronic equipment EE on the power supply terminal V
- the impact of the impact improves the stability of the power supply terminal V.
- the electronic equipment EE provided in Fig. 30 can transmit the modulated signal (which can be a monotone signal or a high-frequency AC Signals, such as high-frequency amplitude signals, high-frequency phase signals, etc.) are amplified to obtain amplified modulated signals. It avoids the impact of the electronic equipment EE on the same power supply (namely, the power supply terminal V in FIG. 30 ) when the electronic equipment EE is turned on, and the electronic equipment EE has high reliability, small size, and low cost.
- the modulated signal which can be a monotone signal or a high-frequency AC Signals, such as high-frequency amplitude signals, high-frequency phase signals, etc.
- the embodiment of the present application also provides an electronic device EE (which may be referred to as a multi-channel power circuit), and the electronic device EE includes R power circuits (that is, the power circuit AMP1 in FIG. 32 , power circuit AMP2, ..., power circuit AMPR), R power circuits are coupled in parallel.
- IN in FIG. 32 represents the signal source of the electronic device EE, and OUT represents the output terminal of the electronic device EE.
- the electronic equipment EE may further include a splitter S and a combiner C, as shown in FIG. 33 .
- the electronic equipment EE includes a splitter S, R power circuits (that is, power circuits AMP1, power circuits AMP2, ..., power circuits AMPR in Fig. 33) and a combiner C, and the R power circuits are connected in parallel mode coupling.
- the splitter S divides the modulation signal from the signal source IN into N paths, and the N paths of modulation signals respectively enter the power circuit AMP1, the power circuit AMP2, . . . , the power circuit AMPR.
- the combiner C combines the respective output signals from the power circuit AMP1 , the power circuit AMP2 , .
- the electronic equipment EE includes three power circuits including a power circuit AMP1 , a power circuit AMP2 and a power circuit AMP3 , and the power circuit AMP1 , power circuit AMP2 and power circuit AMP3 are coupled in parallel.
- the power circuit AMP1 includes a power module A11 (refer to the introduction about the power subunit A10 above), and a current source unit that provides supply current for the power module A11 (not shown in FIG. The introduction of A21) and the bias unit that outputs the supply voltage V bias1 based on the supply current (not shown in FIG. 34 , please refer to the introduction about the bias unit A23 above).
- the power circuit AMP2 includes a power module A12 (refer to the introduction about the power subunit A10 above), and a current source unit that provides power supply current for the power module A12 (not shown in FIG. ) and a bias unit that outputs the supply voltage V bias2 based on the supply current (not shown in FIG. 34 , please refer to the introduction about the bias unit A23 above).
- the power circuit AMP3 includes a power module A13 (refer to the introduction about the power subunit A10 above), and a current source unit (not shown in FIG. 34 ) that provides power supply current for the power module A13. Refer to the introduction about the bias unit A23 above) and the bias unit that outputs the supply voltage V bias3 based on the supply current (not shown in FIG. 34 , refer to the introduction about the bias unit A23 above).
- the power modules A11 to A13 all include power transistors (taking NMOS transistors as an example). It can be understood that the drains of the NMOS transistors of the power module A11, the drains of the NMOS transistors of the power module A12 and the drains of the NMOS transistors of the power module A13 can be respectively connected to the corresponding +VDD (that is, the power supply terminal V in FIG.
- the electronic equipment EE when it receives a control signal such as a TDD signal, it can obtain a slowly increasing supply current through the current source unit of the power circuit AMP1 in FIG. 34 . Based on the slowly increasing supply current, a slowly increasing supply voltage V bias1 is obtained through the current source unit and the bias unit of the power circuit AMP1 in FIG. 34 . Similarly, the slowly increasing supply voltage V bias2 can be obtained through the current source unit and bias unit of the power circuit AMP2 in Figure 34, and can also be slowly increased through the current source unit and bias unit of the power circuit AMP3 in Figure 34 supply voltage V bias3 .
- the delay interval that can be set by the delay unit is between the power circuit AMP1 and the power circuit AMP2
- set the delay interval between the power circuit AMP2 and the power circuit AMP3 that is, between each channel
- delay The time interval is shown as ⁇ in 31, which further reduces the impact of the electronic equipment EE on the power supply terminal V, thereby reducing the voltage fluctuation of the power supply terminal V and improving the stability of the power supply terminal V.
- the electronic equipment EE provided in Figure 34 can transmit the modulated signal from the signal source IN (which can be a monotone signal or a high-frequency AC Signals, such as high-frequency amplitude signals, high-frequency phase signals, etc.) are amplified to obtain amplified modulated signals. It avoids the impact of the amplifying circuit of the electronic equipment EE on different power sources (that is, multiple power supply terminals V in FIG. 34 ) at the moment of turning on the electronic equipment EE.
- the multi-channel electronic equipment EE has high reliability, small size and low cost.
- sequence numbers of the above-mentioned processes do not mean the order of execution, and the execution order of the processes should be determined by their functions and internal logic, and should not be used in the embodiments of the present application.
- the implementation process constitutes any limitation.
- the disclosed systems, devices and methods may be implemented in other ways.
- the device embodiments described above are only illustrative.
- the division of the units is only a logical function division. In actual implementation, there may be other division methods.
- multiple units or components can be combined or May be integrated into another system, or some features may be ignored, or not implemented.
- the mutual coupling or direct coupling or communication connection shown or discussed may be through some interfaces, and the indirect coupling or communication connection of devices or units may be in electrical, mechanical or other forms.
- the units described as separate components may or may not be physically separated, and the components shown as units may or may not be physical units, that is, they may be located in one place, or may be distributed to multiple network units. Part or all of the units can be selected according to actual needs to achieve the purpose of the solution of this embodiment.
- each functional unit in each embodiment of the present application may be integrated into one processing unit, each unit may exist separately physically, or two or more units may be integrated into one unit.
- the functions described above are realized in the form of software function units and sold or used as independent products, they can be stored in a computer-readable storage medium.
- the technical solution of the present application is essentially or the part that contributes to the prior art or the part of the technical solution can be embodied in the form of a software product, and the computer software product is stored in a storage medium, including Several instructions are used to make a computer device (which may be a personal computer, a server, or a network device, etc.) execute all or part of the steps of the methods described in the various embodiments of the present application.
- the aforementioned storage medium includes: U disk, mobile hard disk, read only memory (Read Only Memory, ROM), random access memory (Random Access Memory, RAM), magnetic disk or optical disk and other various media that can store program codes.
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Abstract
Description
Claims (24)
- 一种功率放大电路,其特征在于,包括功率放大模块和与所述功率放大模块耦合的供电模块;所述功率放大模块被配置为:以分时上电的方式供电;所述供电模块包括多个供电子单元,所述多个供电子单元耦合有各自的控制信号线,所述控制信号线之间耦合有延时单元,所述控制信号线用于控制所述供电模块根据所述延迟单元设置的时延以所述分时上电的方式给所述功率放大模块供电。
- 根据权利要求1所述的功率放大电路,其特征在于,所述功率放大模块包括多个功率子单元;所述供电模块用于给所述多个功率子单元以所述分时上电的方式供电。
- 根据权利要求1或2所述的功率放大电路,其特征在于,所述供电子单元包括电流源单元和开关单元;所述电流源单元包括多个电流源,所述开关单元包括多个开关,所述多个电流源与所述多个开关一一对应耦合;所述多个开关被配置为:基于所述控制信号线提供的控制信号控制所述多个电流源为所述功率放大模块供电。
- 根据权利要求1至3中任一项所述的功率放大电路,其特征在于,所述供电子单元包括电压源单元,所述电压源单元包括一个电压源;所述电压源被配置为:基于所述控制信号线提供的控制信号为所述功率放大模块供电。
- 根据权利要求1至4中任一项所述的功率放大电路,其特征在于,所述供电模块还包括偏置单元,所述偏置单元的输入端与所述多个供电子单元的输出端耦合,所述偏置单元的输出端与所述功率放大模块的输入端耦合;所述供电子单元还被配置为:为所述偏置单元提供供电电流;所述偏置单元被配置为:基于所述供电电流为所述功率放大模块提供供电电压。
- 根据权利要求2所述的功率放大电路,其特征在于,所述功率子单元包括一个功率管和一个负载阻抗;所述功率管的控制极与所述供电模块的输出端耦合,所述功率管的第一极通过所述负载阻抗与电源端耦合,所述功率管的第二极与接地端耦合。
- 根据权利要求6所述的功率放大电路,其特征在于,所述功率管为三极管;所述三级管的基极与所述供电模块的输出端耦合,所述三级管的集电极通过所述负载阻抗与电源端耦合,所述三级管的发射极与接地端耦合。
- 根据权利要求6所述的功率放大电路,其特征在于,所述功率管为场效应管;所述场效应管的栅极与所述供电模块的输出端耦合,所述场效应管的漏极通过所述负载阻抗与电源端耦合,所述场效应管的源极与接地端耦合。
- 根据权利要求2所述的功率放大电路,其特征在于,所述功率子单元包括多个功率管、多个第一开关和负载阻抗,所述多个功率管与所述多个第一开关一一对应;所述功率管的控制极通过对应的第一开关与所述供电模块的输出端耦合,所述功率管的第一极通过所述负载阻抗与电源端耦合,所述功率管的第二极与接地端耦合。
- 根据权利要求9所述的功率放大电路,其特征在于,所述功率管为三极管;所述三级管的基极通过对应的第一开关与所述供电模块的输出端耦合,所述三级管的集电极通过所述负载阻抗与电源端耦合,所述三级管的发射极与接地端耦合。
- 根据权利要求9所述的功率放大电路,其特征在于,所述功率管为场效应管;所述场效应管的栅极通过对应的第一开关与所述供电模块的输出端耦合,所述场效应管的漏极通过所述负载阻抗与电源端耦合,所述场效应管的源极与接地端耦合。
- 根据权利要求2所述的功率放大电路,其特征在于,所述功率子单元包括多个功率管、多个第二开关和负载阻抗,所述多个功率管与所述多个第二开关一一对应;所述功率管的控制极与所述供电模块的输出端耦合,所述功率管的第一级通过所述负载阻抗和对应的第二开关与所述电源端耦合,所述功率管的第二极与所述接地端耦合。
- 根据权利要求12所述的功率放大电路,其特征在于,所述功率管为三极管;所述三级管的基极与所述供电模块的输出端耦合,所述三级管的集电极通过所述负载阻抗和对应的第二开关与所述电源端耦合,所述三级管的发射极与所述接地端耦合。
- 根据权利要求12所述的功率放大电路,其特征在于,所述功率管为场效应管;所述场效应管的栅极与所述供电模块的输出端耦合,所述场效应管的漏极通过所述负载阻抗和对应的第二开关与所述电源端耦合,所述场效应管的源极与所述接地端耦合。
- 根据权利要求2所述的功率放大电路,其特征在于,所述功率子单元包括多个功率管、多个第一开关、多个第二开关和负载阻抗,所述多个功率管与所述多个第一开关和所述多个第二开关一一对应;所述功率管的控制极通过对应的第一开关与所述供电模块的输出端耦合,所述功率管的第一级通过所述负载阻抗和对应的第二开关与所述电源端耦合,所述功率管的第二极与所述接地端耦合。
- 根据权利要求15所述的功率放大电路,其特征在于,所述功率管为三极管;所述三级管的基极通过对应的第一开关与所述供电模块的输出端耦合,所述三级管的集电极通过所述负载阻抗和对应的第二开关与所述电源端耦合,所述三级管的发射极与所述接地端耦合。
- 根据权利要求15所述的功率放大电路,其特征在于,所述功率管为场效应管;所述场效应管的栅极通过对应的第一开关与所述供电模块的输出端耦合,所述场效应管的漏极通过所述负载阻抗和对应的第二开关与所述电源端耦合,所述场效应管的源极与所述接地端耦合。
- 根据权利要求6至8中任一项所述的功率放大电路,其特征在于,所述功率子单元还包括一个隔直电容和一个偏置电感;其中,所述隔直电容设置于所述功率管的控制极与连接信号源之间,所述偏置电感设置于所述功率管的控制极与所述供电模块之间。
- 根据权利要求9至17中任一项所述的功率放大电路,其特征在于,所述功率子单元还包括多个隔直电容和多个偏置电感,所述多个隔直电容、所述多个偏置电感和所述多个功率管一一对应;所述隔直电容的一端与信号源耦合,所述隔直电容的另一端与功率管的控制极耦合;所述偏置电感的一端与所述供电模块耦合,所述偏置电感的另一端与所述功率管的控制极耦合。
- 根据权利要求5所述的功率放大电路,其特征在于,所述偏置单元包括三极管或场效应管。
- 根据权利要求1至20中任一项所述的功率放大电路,其特征在于,所述功率放大模块为功率放大器PA,用于在时分双工TDD模式下的发射时隙下工作。
- 根据权利要求1至20中任一项所述的功率放大电路,其特征在于,所述功率放大模块为低噪声放大器LNA,用于在时分双工TDD模式下的接收时隙下工作。
- 一种电子设备,其特征在于,包括多个如权利要求1至22中任一项所述的功率放大电路;多个所述功率放大电路通过串联方式或并联方式耦合。
- 根据权利要求23所述的电子设备,其特征在于,还包括电路板;所述功率放大电路设置于所述电路板上。
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CN202180086762.6A CN116670620A (zh) | 2021-05-31 | 2021-05-31 | 功率电路和电子设备 |
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US20240097630A1 (en) | 2024-03-21 |
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