CN112148052B - Portable adjustable stable alternating-current high-voltage generation system - Google Patents

Abstract

A portable adjustable stable alternating current high voltage generating system utilizes a phase-locked loop to generate signals with different frequencies, and controls the frequency conversion of the phase-locked loop through a serial port. The high-voltage booster is stabilized on the voltage corresponding to a certain booster within the limit output power of all amplifiers by setting the level of an output pin of a single chip microcomputer, the system can detect over-high voltage and over-low voltage, and the input power of a subsequent power amplifier is adjusted by changing the gain of the Variable Gain Amplifier (VGA) so that if the output voltage of the booster corresponding to the output power of the power amplifier is greater than a desired value, the output power of the power amplifier is reduced by the AGC system to reduce the final voltage, and vice versa. The system can be changed according to the required condition so as to meet the requirement that the system has high power output efficiency under different frequencies and can efficiently provide power for the booster. The system is small in size, and convenient to operate only by controlling the single chip microcomputer through a small computer.

Description

Portable adjustable stable alternating-current high-voltage generation system

Technical Field

The invention belongs to the technical field of high-voltage equipment, and particularly relates to a portable adjustable stable alternating-current high-voltage generator.

Background

The existing boosting devices are large and difficult to raise a large voltage with a relatively small power, most of the existing devices do not have a flexible frequency conversion boosting function, and most of the existing devices do not keep the voltage constant for a long time, so that the output voltage is unstable along with environmental changes (interference or temperature changes). The rechargeable battery can be used for emergency temporarily when no external power supply is available. The invention has the advantages of small size, portability and capability of raising a relatively large voltage by using a small power. The invention can stabilize output voltage in different environments, has temperature compensation measures in a power amplifier system, has an AGC feedback system in an integral system, is very suitable for being used as a laboratory high generator and temporary emergency high-voltage generating equipment of a high-voltage electric field, is suitable for places with strict requirements such as medicine, military, scientific research and the like, has a special stabilizing system and a convenient operating system, and greatly improves the reliability and operability of the invention.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention aims to provide a portable adjustable stable alternating-current high-voltage generating system, which utilizes a phase-locked loop to generate signals with different frequencies and controls the frequency conversion of the phase-locked loop through a serial port. An automatic gain control AGC system is formed by the variable gain amplifier VGA, the operational amplifier and the peak detector, the high-voltage booster is stabilized on the voltage corresponding to a certain booster within the limit output power of all amplifiers by setting the level of an output pin of the singlechip, the system can detect over-high voltage and over-low voltage, the input power of the power amplifier at the later stage is adjusted by changing the gain of the VGA amplifier of the variable gain amplifier, and if the output voltage of the booster corresponding to the output power of the power amplifier is larger than the expected value, the output power of the power amplifier is reduced by the AGC system to reduce the final voltage, and vice versa. The system has automatic protection, and when the voltage of the system is too high due to self-excitation or misoperation, if the voltage of the comparator is higher than the preset level of the singlechip, the comparator can output high level and simultaneously cut off the input signals of the power supply and the power amplifier.

In order to achieve the purpose, the invention adopts the technical scheme that:

a portable adjustable stable alternating current high voltage generating system comprises a single chip microcomputer (5), and is characterized in that a small computer (16) is connected with the single chip microcomputer (5); the singlechip (5) is respectively connected with the comparator (4), the electric regulation switch A (6), the operational amplifier (14), the phase-locked loop (17), the stepping motor A (18) and the stepping motor B (19); the phase-locked loop (17) is connected with the variable gain amplifier VGA (15); the variable gain amplifier VGA (15) is connected with the electrically-regulated switch A (6); the electric regulation switch A (6) is respectively connected with a power amplifier A (7), a power amplifier B (8) and a power amplifier C (9); the power amplifier A (7), the power amplifier B (8) and the power amplifier C (9) are connected with an electric regulation switch B (10); the electric regulation switch B (10), the stepping motor A (18) and the stepping motor B (19) are connected with the high-voltage booster (11); one end of the high-voltage booster (11) outputs, and the other end of the high-voltage booster is connected with the voltage reduction circuit (12); the voltage reduction circuit (12) is connected with the detector (13); the detector (13) is respectively connected with the comparator (4) and the operational amplifier (14); the operational amplifier (14) is connected with a variable gain amplifier VGA (15); the comparator (4) is respectively connected with the power supply switch (3) and the electric regulation switch A (6); the power supply switch (3) is connected with the rechargeable battery (2) and the power adapter (1); the power adapter (1) is connected with the rechargeable battery (2); the input end of the power adapter (1) is connected with 220V.

The power amplifying circuit comprises an electric adjusting switch A (6), a power amplifier A (7), a power amplifier B (8), a power amplifier C (9) and an electric adjusting switch B (10), wherein four D Zener in the circuit are all voltage stabilizing diodes, a capacitor C1, a capacitor C2, a capacitor C3, a capacitor C4, a capacitor C5, a capacitor C6, a capacitor C7, a capacitor C8, a capacitor C9, a capacitor C10, a capacitor C11, a capacitor C12, a capacitor C13, a capacitor C14, a capacitor C15, a capacitor C16, a capacitor C17, a capacitor C18, a capacitor C19, a capacitor C20, a capacitor CAP1, a capacitor CAP2, a capacitor CAP3, a capacitor CAP4, an inductor L1, an inductor L2, an inductor L3, an inductor L4, an inductor L5, a resistor R1, a resistor R2, a resistor R3, a resistor R5, a resistor R6, a resistor R8, a sliding rheostat R4, a sliding rheostat R7, a power amplifier Q1 and a rheostat Q2.

The electric regulation switch B (10) is connected with a transmission line through an SMA adapter, and then is connected with a high-voltage booster (11) through the transmission line, and the input of the high-voltage booster (11) is accessed by a coaxial line.

Further, adopt the input/output matching circuit who contains varactor, replace former electrically transferred switch A (6) by input matching circuit A (20) that contain varactor, electrically transferred switch B (10) is replaced by input matching circuit B (21) that contain varactor, and the structure is as follows:

the small computer (16) is connected with the singlechip (5); the singlechip (5) is respectively connected with the comparator (4), an input matching circuit A (20) containing a variable capacitance diode, a power amplifier A (7), an operational amplifier (14), a phase-locked loop (17), a stepping motor A (18) and a stepping motor B (19); the phase-locked loop (17) is connected with the variable gain amplifier VGA (15); the variable gain amplifier VGA (15) is connected with an input matching circuit A (20) containing a variable capacitance diode; an input matching circuit A (20) containing a variable capacitance diode is connected with a power amplifier A (7); the power amplifier A (7) is connected with an input/output matching circuit B (21) containing a variable capacitance diode; an input/output matching circuit B (21) containing a variable capacitance diode, a stepping motor A (18) and a stepping motor B (19) are connected with the high-voltage booster (11); one end of the high-voltage booster (11) outputs, and the other end of the high-voltage booster is connected with the voltage reduction circuit (12); the voltage reduction circuit (12) is connected with the detector (13); the detector (13) is respectively connected with the comparator (4) and the operational amplifier (14); the operational amplifier (14) is connected with a variable gain amplifier VGA (15); the comparator (4) is connected with the power supply switch (3); the power supply switch (3) is connected with the rechargeable battery (2) and the power adapter (1); the power adapter (1) is connected with the rechargeable battery (2); the input end of the power adapter (1) is connected with 220V.

The input matching circuit A (20) containing the variable capacitance diode is connected with the power amplifier A (7); the power amplifier A (7) is connected with an input and output matching circuit B (21) comprising a variable capacitance diode to form a power amplifying circuit, wherein four D Zener in the circuit are all voltage stabilizing diodes, a capacitor C1, a capacitor C2, a capacitor C3, a capacitor C4, a capacitor C5, a capacitor C6, a capacitor C7, a capacitor C8, a capacitor C9, a capacitor C10, a capacitor C11, a capacitor C12, a capacitor C13, a capacitor C14, a variable capacitance diode D1, a variable capacitance diode D2, a variable capacitance diode D3, a variable capacitance diode D4, a variable capacitance diode D5, a variable capacitance diode D6, a capacitor CAP1, a capacitor CAP2, a capacitor CAP3, a capacitor CAP4, an inductor L1, an inductor L2, an inductor L3, an inductor L4, an inductor L5, a resistor R1, a resistor R2, a resistor R3, a resistor R5, a resistor R6, a resistor R8, a slide rheostat R4, a slide rheostat R7, a power amplifier Q1 and a power amplifier Q2.

The output end of the input/output matching circuit B (21) containing the variable capacitance diode is connected with a transmission line through an SMA adapter, and then is connected with the high-voltage booster (11) through the transmission line, and the input of the high-voltage booster (11) is accessed by a coaxial line.

The single chip microcomputer adopts an MSP430F438 single chip microcomputer.

The single chip microcomputer (5) is connected with a phase-locked loop (17) through a serial port, and the output of an ADF4351 of the phase-locked loop (17) is connected with a variable gain amplifier VGA (15) ADL5331.

The voltage reduction circuit (12) is composed of two 50K ohm resistors R1 and R2, a 1:1 balun K1 and a 50 ohm resistor R3.

The high-voltage booster (11) is as follows: an inductance fixing rod (23) and a plectrum guide rod (27) are fixed in the metal shell (22), and two ends of a plectrum moving rod (28) penetrate through the metal shell (22); an inductor I (24) and an inductor III (26) are wound at two ends of the inductor fixing rod (23), and an inductor II (25) is wound in the middle of the inductor fixing rod; one ends of the first inductor (24), the second inductor (25) and the third inductor (26) are grounded, the other ends of the first inductor (24) and the third inductor (26) are fixed on the inductor fixing rod (23), and the other end of the second inductor (25) is connected with a resistor and an inductor; both ends are connected the metal pole for non-conductive material on plectrum carriage release lever (28), metal pole connecting rod, and non-conductive material is connected to the threaded rod intermediate junction, and each cover has a plectrum (29) on two sections threaded rods, and plectrum (29) below through-hole is run through by plectrum guide bar (27), and coupling nut (30) on the metal pole at plectrum carriage release lever (28) both ends, electricity intercommunication between two nuts (30) is equipped with parallelly connected resistance and electric capacity.

The phase-locked loop (17), the stepping motor A (18), the stepping motor B (19), the electric regulation switch A (6), the electric regulation switch B (10), the input matching circuit A (20) with the variable capacitance diode and the variable capacitance diode variable capacitance voltage of the input matching circuit B (21) with the variable capacitance diode are all controlled by the single chip microcomputer (5), and the variable gain amplifier VGA (15) is indirectly controlled by the single chip microcomputer through the operational amplifier (14) by generating a reference signal.

The invention has the beneficial effects that:

the system can control two stepping motors through the single chip microcomputer, the two stepping motors are respectively connected with two knobs of the booster, one of the knobs can control the adjustable capacitance of a primary side circuit of the booster, and the designed booster is used for enabling a primary side circuit and a secondary side circuit to respectively resonate for boosting, so that resonance points of two positions are required to be adjusted simultaneously during frequency conversion. The first stepping motor is used for adjusting the variable capacitance of the primary end of the booster so as to achieve the purpose of realizing the resonance of the primary end circuit. The second stepping motor is used for adjusting the resonant frequency of the booster secondary end circuit, the inductance value of the coil is adjusted by changing the different connecting positions of the connecting plectrum and the coil, so that the second stepping motor and the subsequent synchronous tube are changed, the second stepping motor is equivalent to the resonant frequency of a capacitor to enable the booster to keep a high Q value under different frequencies, and high-efficiency boosting under each frequency is guaranteed, namely, a higher boosting effect under the same power can be guaranteed by the high Q value.

The power amplifier of the system is a key design, the system is realized by two implementation methods, one implementation method is that an input and output matching network under various fixed frequencies is designed, different matching circuits are switched by utilizing an electrically-adjustable switch, each matching circuit has a certain bandwidth and can meet the matching in a frequency band, and the single chip microcomputer switches the selection of the matching circuits according to the fact that a certain frequency corresponds to a certain bandwidth. And two power amplifiers are implemented, the input and the output of each power amplifier comprise a variable capacitance diode, and the matching impedance of the power amplifiers is changed by changing the variable capacitance diodes so as to meet the matching of the power amplifiers under different frequencies and ensure the efficient output of power. The first implementation has the advantage of convenient design and space saving, but the adjustable range is relatively narrow. The second implementation has the advantage of wide adjustable range, but occupies relatively large space.

The system has automatic protection, and when the voltage of the system is too high due to self-excitation or misoperation, if the voltage of the comparator is higher than the preset level of the singlechip, the comparator can output high level and simultaneously cut off the input signals of the power supply and the power amplifier.

The system is provided with a rechargeable battery to meet the use requirement of emergency situations, and is also provided with a transformer for direct power plug-in use. The AGC system can output stable voltage. The booster can adjust frequency and amplitude, and can output large voltage by using relatively small power. The power amplifier matching circuit can be changed according to the required condition so as to meet the requirement of high power output efficiency under different frequencies, and the booster can be efficiently supplied with power. The system is small in size, and convenient to operate only by controlling the single chip microcomputer through a small computer.

Both schemes are true for matching of power amplifiers, since high frequency power amplifiers need to add input-output matching for the frequency at which they operate to ensure efficient transfer of energy. Therefore, the output power of each frequency which can be provided externally must be ensured, so two matching modes are considered here, (1) one is to use a plurality of paths of power amplifiers, each path of power amplifier is provided with an input-output matching network with a certain bandwidth (the bandwidth is not as wide as dozens of MHz), then the singlechip judges the frequency band to which the selected frequency belongs according to the selection of a user, and then controls the electrically-controlled switch to open the corresponding channel to connect the power amplifiers of the response frequency band. (2) The other is that some variable capacitance diodes (the capacitance value of which can be changed along with the bias direct-current voltage) are added in the input and output matching circuit, and the single chip microcomputer provides different voltages to control the capacitance value of each variable capacitance diode so as to realize the change of the matching resonance point, so that only one power amplifier is needed, and only the variable capacitance diodes are needed to be adjusted to change the resonance point of the matching circuit.

For the first method, because a corresponding matching circuit is provided for a specific frequency band, in this case, relatively low power consumption and a relatively high Q (quality factor) value of the matching network can be achieved, and the out-of-band rejection is generally relatively high, but a large number of power amplifiers are required, the occupied area is large, and the cost is relatively high. In the second method, only one power amplifier capable of working in a wider frequency band, one input/output matching network and several varactors are needed, so that the circuit occupation is relatively small, the cost is relatively low, but theoretically, the matching network performance optimization is realized by simultaneously changing the capacitance and the inductance value during matching tuning, so that the matching frequency of the varactors can not reach the best performance, but the corresponding index can be realized, the efficiency of the power amplifier is possibly relatively low, and the Q value of the matching network is relatively low. However, for the system designed by me, the power amplifier only needs to provide the power required by the booster, so that the power amplifier is not necessarily required to exert the best performance when the power amplifier is designed.

Therefore, the effect of the two methods is almost the same when only the boosting effect is seen, and the first method needs to be selected to be better when the seed efficiency is seen. The second method is preferred if a small volume is required.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a second embodiment of the present invention;

FIG. 3 is a circuit diagram of a power amplifier according to an embodiment of the present invention;

FIG. 4 is a circuit diagram of a power amplifier according to a second embodiment of the present invention;

FIG. 5 is a circuit diagram of a buck-boost circuit according to the present invention;

FIG. 6 is a schematic diagram of the high voltage booster of the present invention;

FIG. 7 is an experimental test chart of the booster output voltage;

FIG. 8 is an experimental test chart of the booster output voltage;

FIG. 9 is a linear diagram of an operational amplifier

Wherein, 1 is a power adapter; 2 is a rechargeable battery; 3 is a power supply switch; 4 is a comparator; 5 is a singlechip; 6 is an electric regulation switch A;7 is a power amplifier A;8 is a power amplifier B;9 is a power amplifier C;10 is an electric regulation switch B;11 is a high-voltage booster; 12 is a voltage reduction circuit; a detector 13; 14 is an operational amplifier; 15 is a variable gain amplifier VGA;16 is a small computer; 17 is a phase-locked loop; 18 is a stepping motor A;19 is a stepping motor B;20 is an input-output matching circuit A containing a variable capacitance diode; 21 is an input-output matching circuit B containing a variable capacitance diode; 22 is a metal shell; 23 is an inductance fixing rod; 24 is an inductor I; 25 is an inductor II; 26 is inductor three; 27 is a plectrum guide rod; 28 is a shifting block moving rod; 29 is a shifting piece; and 30 is a nut.

Detailed Description

The invention is further described below with reference to the accompanying drawings.

Implementing one step:

as shown in fig. 1, a portable adjustable stable alternating current high voltage generating system comprises a single chip microcomputer (5), and is characterized in that a small computer (16) is connected with the single chip microcomputer (5); the singlechip (5) is respectively connected with the comparator (4), the electric regulation switch A (6), the operational amplifier (14), the phase-locked loop (17), the stepping motor A (18) and the stepping motor B (19); the phase-locked loop (17) is connected with the variable gain amplifier VGA (15); the variable gain amplifier VGA (15) is connected with the electrically-regulated switch A (6); the electric regulation switch A (6) is respectively connected with a power amplifier A (7), a power amplifier B (8) and a power amplifier C (9); the power amplifier A (7), the power amplifier B (8) and the power amplifier C (9) are connected with an electric regulation switch B (10); the electric regulation switch B (10), the stepping motor A (18) and the stepping motor B (19) are connected with the high-voltage booster (11); one end of the high-voltage booster (11) outputs, and the other end of the high-voltage booster is connected with the voltage reduction circuit (12); the voltage reduction circuit (12) is connected with the detector (13); the detector (13) is respectively connected with the comparator (4) and the operational amplifier (14); the operational amplifier (14) is connected with a variable gain amplifier VGA (15); the comparator (4) is respectively connected with the power supply switch (3) and the electric regulation switch A (6); the power supply switch (3) is connected with the rechargeable battery (2) and the power adapter (1); the power adapter (1) is connected with the rechargeable battery (2); the input end of the power adapter (1) is connected with 220V.

As shown in fig. 3, the power amplifying circuit is composed of an electrically tunable switch a (6), a power amplifier a (7), a power amplifier B (8), a power amplifier C (9), and an electrically tunable switch B (10), and includes a power amplifier MRFE6VS25N, a capacitor, an inductor, a resistor, a variable resistor, and a zener diode. In the circuit, four D Zener are voltage-stabilizing diodes, the positive input ends of the diodes are connected in series to the ground, and the other ends of the diodes are connected with a capacitor C1, a capacitor C2, a capacitor C3, a capacitor C4, a capacitor CAP1, a capacitor CAP2, a resistor R3 and a resistor R5. The other ends of the capacitor C1, the capacitor C2, the capacitor C3, the capacitor C4, the capacitor CAP1 and the capacitor CAP2 are all grounded. The other end of the resistor R2 is connected with the resistor R1 and a power supply VCC, and the four parallel capacitors, the capacitor C5, the capacitor C6, the capacitor C7, the capacitor CAP3 and the inductor L1 are connected. The other end of R1 is connected with four parallel capacitors, a capacitor C8, a capacitor C9, a capacitor C10, a capacitor CAP4 and an inductor L2. The other end of the inductor L3 is connected with a capacitor C13 with the other end grounded and a capacitor C11 with the other end connected with an output end (RF OUT). The source (3) of the power amplifier Q1 is grounded, the grid (2) of the power amplifier Q1 is connected with a tap of a capacitor C15 and a tap of a slide rheostat R7, and one end of the other end of the slide rheostat R7 is connected with a resistor R8 and a resistor R5, the other end of the resistor R8 is grounded. The other end of the capacitor C15 is connected to a capacitor C17 with the other end grounded and an inductor L4. The other end of the inductor L4 is connected to a capacitor C16 and a capacitor C14, the other ends of which are connected to ground. Capacitor C14 is connected to inductor L2 and the drain (reference numeral 1) of power amplifier Q2. The source (reference numeral 3) of the power amplifier Q2 is connected to ground. The gate (reference numeral 2) of the power amplifier Q2 is connected to a capacitor C20 with the other end grounded and to a tap of an inductor L5 and a sliding varistor R4. The other two ends of the sliding rheostat are connected with the resistor R6 with the other end grounded and the other end connected with the resistor R3. The other terminal of the inductor L5 is connected to a capacitor C19, the other terminal of which is connected to ground, and a capacitor C18, the other terminal of which is connected to the input terminal (RF IN).

The electric regulation switch B (10) is connected with a transmission line through an SMA adapter, and then is connected with a high-voltage booster (11) through the transmission line, and the input of the high-voltage booster (11) is accessed by a coaxial line.

Carry out two

As shown in fig. 2, an input/output matching circuit including a varactor is adopted, an original electrically tunable switch a (6) is replaced by an input matching circuit a (20) including a varactor, and an electrically tunable switch B (10) is replaced by an input matching circuit B (21) including a varactor, and the structure is as follows:

the small computer (16) is connected with the singlechip (5); the singlechip (5) is respectively connected with the comparator (4), an input matching circuit A (20) containing a variable capacitance diode, a power amplifier A (7), an operational amplifier (14), a phase-locked loop (17), a stepping motor A (18) and a stepping motor B (19); the phase-locked loop (17) is connected with the variable gain amplifier VGA (15); the variable gain amplifier VGA (15) is connected with an input matching circuit A (20) containing a variable capacitance diode; an input matching circuit A (20) containing a variable capacitance diode is connected with a power amplifier A (7); the power amplifier A (7) is connected with an input-output matching circuit B (21) containing a variable capacitance diode; an input/output matching circuit B (21) containing a variable capacitance diode, a stepping motor A (18) and a stepping motor B (19) are connected with the high-voltage booster (11); one end of the high-voltage booster (11) outputs, and the other end of the high-voltage booster is connected with the voltage reduction circuit (12); the voltage reduction circuit (12) is connected with the detector (13); the detector (13) is respectively connected with the comparator (4) and the operational amplifier (14); the operational amplifier (14) is connected with a variable gain amplifier VGA (15); the comparator (4) is connected with the power supply switch (3); the power supply switch (3) is connected with the rechargeable battery (2) and the power adapter (1); the power adapter (1) is connected with the rechargeable battery (2); the input end of the power adapter (1) is connected with 220V.

As shown in fig. 4, the input matching circuit a (20) with the varactor diode is connected with a power amplifier a (7); the power amplifier A (7) is connected with an input/output matching circuit B (21) group of power amplifying circuits comprising variable capacitance diodes, and comprises a power amplifier MRFE6VS25N, a capacitor, an inductor, a resistor, a variable resistor and a voltage stabilizing diode. In the circuit, four D Zener are voltage-stabilizing diodes, the positive input ends of the diodes are connected in series to the ground, and the other ends of the diodes are connected with a capacitor C1, a capacitor C2, a capacitor C3, a capacitor C4, a capacitor CAP1, a capacitor CAP2, a resistor R3 and a resistor R5. The other ends of the capacitor C1, the capacitor C2, the capacitor C3, the capacitor C4, the capacitor CAP1 and the capacitor CAP2 are all grounded. The other end of the resistor R2 is connected with the resistor R1 and a power supply VCC, and the four parallel capacitors, the capacitor C5, the capacitor C6, the capacitor C7, the capacitor CAP3 and the inductor L1 are connected. The other end of R1 is connected with four parallel capacitors, a capacitor C8, a capacitor C9, a capacitor C10, a capacitor CAP4 and an inductor L2. The other end of the L1 is connected with a variable capacitance diode D1 with the grounded positive end, an inductor L3 and a drain electrode (labeled 1) of the power amplifier Q1, and the other end of the inductor L3 is connected with a variable capacitance diode D2 with the grounded positive end and a capacitor C11 with the other end connected with an output end (RF OUT). The source (3) of the power amplifier Q1 is grounded, the grid (2) of the power amplifier Q1 is connected with a tap of a capacitor C13 and a slide rheostat R7, and one end of the other end of the slide rheostat R7 is connected with a resistor R8 and a resistor R5, the other end of the slide rheostat R7 is grounded. The other end of the capacitor C13 is connected to a varactor D4 with a grounded positive terminal and an inductor L4. The other end of the inductor L4 is connected to a varactor D3 with a grounded positive terminal and a capacitor C12. The capacitor C12 is connected to the inductor L2 and the drain (reference numeral 1) of the power amplifier Q2. The source (reference numeral 3) of the power amplifier Q2 is connected to ground. The gate (reference numeral 2) of the power amplifier Q2 is connected to a positive side grounded varactor D6 and to an inductor L5 and to the taps of the sliding rheostat R4. The other two ends of the sliding rheostat are connected with the resistor R6 with the other end grounded and the other end connected with the resistor R3. The other end of the inductor L5 is connected to a varactor D5 with its positive terminal grounded and a capacitor C14 with its other end connected to the input terminal (RF IN);

the output end of the input/output matching circuit B (21) containing the variable capacitance diode is connected with a transmission line through an SMA adapter, and then is connected with the high-voltage booster (11) through the transmission line, and the input of the high-voltage booster (11) is accessed by a coaxial line.

The single-chip microcomputer adopts an MSP430F438 single-chip microcomputer.

The single chip microcomputer (5) is connected with a phase-locked loop (17) through a serial port, and the output of an ADF4351 output end of the phase-locked loop (17) is connected with a variable gain amplifier VGA (15) ADL5331.

As shown in fig. 5, the voltage dropping circuit (12) is composed of two 50K ohm resistors R1 and R2, and a 1:1 balun K1 and a 50 ohm resistor R3. One ends of the resistors R1 and R2 are respectively connected with two ends of the load resistor RL behind the booster. And the other ends of R1 and R2 are respectively connected with two ends of the primary side of the balun K1. One end of the secondary side of the balun K1 is grounded, and the other end of the secondary side of the balun K1 is connected with a resistor R3 with the other end grounded and an output end.

As shown in fig. 6, the high voltage booster (11) is: an inductance fixing rod (23) and a plectrum guide rod (27) are fixed in the metal shell (22), and two ends of a plectrum moving rod (28) penetrate through the metal shell (22); an inductor I (24) and an inductor III (26) are wound at two ends of the inductor fixing rod (23), and an inductor II (25) is wound in the middle of the inductor fixing rod; one ends of the first inductor (24), the second inductor (25) and the third inductor (26) are grounded, the other ends of the first inductor (24) and the third inductor (26) are fixed on the inductor fixing rod (23), and the other end of the second inductor (25) is connected with a resistor and an inductor; both ends are connected the metal pole for non-conductive material on plectrum carriage release lever (28), metal pole connecting rod, and non-conductive material is connected to the threaded rod intermediate junction, and each cover has a plectrum (29) on two sections threaded rods, and plectrum (29) below through-hole is run through by plectrum guide bar (27), and coupling nut (30) on the metal pole at plectrum carriage release lever (28) both ends, electricity intercommunication between two nuts (30) is equipped with parallelly connected resistance and electric capacity.

The phase-locked loop (17), the stepping motor A (18), the stepping motor B (19), the electric regulation switch A (6), the electric regulation switch B (10), the input matching circuit A (20) with the variable capacitance diode and the variable capacitance diode variable capacitance voltage of the input matching circuit B (21) with the variable capacitance diode are all controlled by the single chip microcomputer (5), and the variable gain amplifier VGA (15) is indirectly controlled by the single chip microcomputer through the operational amplifier (14) by generating a reference signal.

Implementing one step:

as shown in fig. 7, 8, and 9, a phase-locked loop (17) used in the experiment is used to generate signals of various frequencies, the phase-locked loop used in the experiment is ADF4351, which can output a minimum-4 dBm power and a maximum 5dBm power at frequencies from 35MHz to 4400MHz (the boosting device is expected to output a high voltage from 50M to 200 MHz), a 10dB attenuator is added behind the phase-locked loop, so that the power input to the variable gain amplifier VGA (15) is approximately-14 dBm to-5 dBm, the variable gain amplifier VGA (15) used in the experiment is ADL5331 (the operating frequency is 1MHz to 1.2 GHz), and a gain from-10 dB to 13dB from 50MHz to 200MHz can be realized according to a data manual. The variable gain amplifier VGA can provide-24 dBm to 8dBm input power for the subsequent power amplifiers (7) (8) (9) at 50MHz to 200MHz.

The rear-stage power amplifiers (7), (8) and (9) both adopt two cascaded LDMOS field effect transistors of MRFE6VS25N, the power amplifiers (7), (8) and (9) can realize 25dB gain and 25W maximum output power from 50MHz to 200MHz, the experiment presets that both the first-stage power amplifier and the second-stage power amplifier are 18dB gain, the experiment can meet the experiment requirement only by requiring that the power amplifiers can output at least 20W (43 dBm) power at most, the first-stage output power of the power amplifiers (7), (8) and (9) can be estimated according to the maximum input power of 8dBm provided by the front-stage circuit, the first-stage output power of the power amplifiers (7), (8) and (9) is approximately 26dBm (0.4W), and the second-stage can achieve the output power of 43dBm (20W) only by requiring 17dB gain. According to the method of the first embodiment, the frequency band range of the power amplifier (7) with the center frequency of 65MHz is 50MHz to 80MHz, the center frequency of the power amplifier (8) is 80MHz to 130MHz, and the center frequency of the power amplifier (9) is 200MHz. In order to achieve the expected target, when the first stage of the power amplifier (7) (8) (9) is designed, the output power of 27dBm (0.5W) is standard when the maximum input is 8dBm, that is, a gain of 19dB is required (preset to 18dB, a margin of 1dB is provided), according to R = U ^ 2/(2P) = (40 x 0.7) ^ 2/(2*1) =392 ohm, the power amplifier (7) (8) (9) recommends that the drain-source voltage is VDS =50V according to a data manual, but according to practical experiments, it can be found that the experimental requirements of the first stage can be met only by supplying 40V with VDS (drain-source voltage), because the first stage VDS is supplied with 40V, and the ac voltage swing cannot reach 40V in practice, here, the ac voltage is set to 0.7 times the dc voltage according to practical experience, and the maximum output power is set to 1W, so that we can certainly estimate the output power of the first stage of 0.5W, and the output impedance of the first stage amplifier calculated according to the above formula, the output impedance of the first stage is approximately 392 ohm. The second stage input impedance of the power amplifiers (7), (8) and (9) need only be matched to 392 ohms. According to the experimental requirement that the output of the second stage power amplifier needs 20W (43 dBm), by estimating that the output impedance of the second stage of the power amplifier (7) (8) (9) needs approximately R = U ^ 2/(2P) = (50 × 0.7) ^ 2/(2 × 20) =31 ohm, only the impedance value of external 50 ohm (the standard input and output impedance of various test equipment and devices is 50 ohm, and when all devices externally present 50 ohm, matching can be realized when the devices are mutually cascaded) needs to be matched to the impedance value of external 31 ohm when the output of the second stage power amplifier is presented, and for the input stage matching of the power amplifier, only the reflection coefficient of the vector network measuring instrument needs to be minimum (because the instrument impedance of the vector network measuring instrument is 50 ohm, the measured result is the minimum reflection coefficient of the power amplifier to 50 ohm, and the input of the power amplifier can be matched without reflection). The power amplifiers (7), (8) and (9) respectively match the impedances of all stages of the 65MHz, 105MHz and 165MHz power amplifiers to the impedances, and the corresponding bandwidth is met through testing. According to actual high-temperature tests, the gains of the whole power amplifier (7), (8) and (9) systems are externally positive-temperature-characteristic, namely, the gains of the power amplifiers are increased along with the increase of temperature, and the stability of the output of the whole system is influenced. Two measures are taken here to ensure that the power amplifiers (7), (8), (9) are affected as little as possible by temperature. Firstly, a proper cavity is designed for a power amplifier board, heat-conducting silicone grease is coated on the power amplifiers of the power amplifiers (7), (8) and (9) and is placed in the cavity, and then a small fan is connected to the back of the cavity by heat-conducting glue, so that the cavity and the fan can provide a heat dissipation effect for the power amplifier.

And secondly, by utilizing the negative temperature characteristic of the Zener diodes, connecting 4 Zener diodes capable of stabilizing voltage of about 2V in series into a VGS (gate source voltage) input bias circuit of the two-stage power amplifier, namely, the voltage can be stabilized to 8V finally, designing a voltage division circuit, adding an adjustable resistor into the voltage division circuit, adjusting the VGS direct current bias voltage to be more than 2.5V, and if the temperature is increased, the voltage stabilization value of the Zener diodes can be reduced to enable the total voltage stabilization value to be less than 8V, so that the power amplifier gain can be reduced when the VGS direct current bias voltage is less than 2.5V, the phenomenon that the power amplifier gain of the original power amplifier system is increased due to the temperature increase is counteracted, and the effect of stable output of the whole power amplifier system is achieved. The power amplifiers (7), (8) and (9) are determined by the frequency set by a user in a small computer (16), and the singlechip (5) controls the electric regulation switch A (6) and the electric regulation switch B (10) to switch on which power amplifier according to the frequency band to which the set frequency belongs. The power amplifier (7) circuit is specifically as follows, and the power amplifiers (8) and (9) are similar in circuit, but the inductance and capacitance values of the input and the output are changed, as shown in fig. 3.

The post-stage booster (11) boosts the voltage by combining the series resonance and the parallel resonance of a capacitor and an inductor, and ensures the high Q value of the disturbed inductor by a silver-plated coil. According to the resonance principle, when the capacitance and the inductance resonate, the maximum energy conversion is obtained, and the discharge energy of one of the capacitance and the inductance is equal to the stored energy of the other one. That is, when L1 and C1 resonate, L1 and C1 can obtain the maximum energy, where the voltage on C1 is U1= (1/C1) × idt, and according to the transformer transformation principle, the voltage of U1 is changed from the primary side of the transformer to the voltage of the secondary side U2, and at this time, if the mutual inductance generated on the secondary side by L3, L4, and L2 can resonate with C2, the maximum voltage can be obtained on the secondary side, and U0= U2= (1/C1) × idt at the same time of resonance. While for different frequency point series resonance we can use the high voltage resistant variable capacitor as C1 (generally, a screw on the variable capacitor can be rotated to change the capacitance value), for parallel resonance we can change the inductance values of the secondary side inductances L3 and L4 by changing the position of the spring plectrum, and estimate the capacitance and inductance value needed to change according to the resonance frequency fc = 1/(LC under 2 pi root). In practice, a stepping motor A (18) and a stepping motor B (19) are respectively connected with a variable capacitor and a rotating shaft of a spring plectrum on the secondary side of a transformer, when the stepping motor A (18) rotates, the capacitor C1 is changed, when the stepping motor B (19) rotates, inductors L3 and L4 are changed, in practice, the capacitors and the inductors at each frequency point during series resonance and parallel resonance can be measured, the rotating angle is measured, the L1 and the C1 can resonate at different frequencies, and the mutual inductance generated by the L3, the L4 and the L2 on the secondary side and the C2 can resonate. R1 and R2 are 50K omega resistors, and form a voltage reduction circuit (12) together with a 1:1 balun K1 and a parallel 50 ohm resistor, and the voltage reduction circuit is connected with a capacitor at the output end of the booster through a transmission line. The 50K Ω resistor is high-impedance relative to the load 5K Ω, so that the influence of the 50K Ω resistor on the load RL is small, the balun K1 plays a role of converting a differential mode into a single-ended mode, and R1: R3= R2: R3=1000, so that the voltage reduction circuit can reduce the high voltage by 2000 times and output the voltage from the U side, as shown in fig. 5.

The U test outputs a voltage proportional to the high voltage, the voltage is input into a detector (13), a power divider is connected behind the detector (13), the signal of the detector (13) is divided into 2 paths, one path is input into an operational amplifier (14), and the other path is input into a comparator (4). The negative input end of the comparator (4) is connected with the power divider, and the positive input end is connected with the singlechip (5). The single chip microcomputer (5) provides a highest safety voltage preset by a booster, the highest safety voltage is subjected to voltage presented by the power divider at the negative end of the comparator (4) through the voltage divider circuit (12) and the detector (13), the voltage is provided for the positive input end and the negative input end to be compared, when the voltage of the negative input end is higher than the voltage, the comparator outputs a high level to turn off the electric regulation switch A (6) and turn off the power supply switch (3), so that a signal input path and a direct current power supply path of equipment are simultaneously turned off, and the equipment is protected.

Fig. 7 and 8 show experimental test diagrams of the output voltage Uo of the booster, and it can be seen that this test is performed by using a 100-time attenuation probe at 91M, and the output voltage can reach 4770V when the power supply power of the power amplifier is 15W (the power supply voltage adopts a double 24V series connection form of 48V, actually we adopt 50V power supply, and the power supply voltage display becomes small due to high-voltage radiation during the experiment, and when the device is installed in a final system metal shell, radiation is not generated to the outside), and it can be seen that the boosting effect of the system is obvious, see fig. 6. According to experimental tests, the highest voltage of the system from 50MHz to 200MHz can reach at least 6000V, the equipment finally takes 6000V as the highest output voltage, and the equipment can provide hundred millivolt-level voltage at minimum.

The booster uses a C2 capacitor that is not high voltage tolerant, a high voltage capacitor having an equivalent parasitic resistance of approximately 5k omega.

The operational amplifier (14) adopts MAX4265, wherein the negative input end voltage of the operational amplifier (14) is the output voltage of the other end of the power divider, the negative input end voltage is a voltage which is corresponding to the output voltage of the booster through the wave detector (13) of the step-down circuit (12) and the power divider one by one according to the output voltage of the booster, and the positive input end of the operational amplifier (14) is a reference voltage provided by the singlechip (5). The subtraction of the negative end voltage from the positive end voltage enables the operational amplifier (14) to output a voltage for controlling the gain of the variable gain amplifier VGA, the control voltage can change the gain of the variable gain amplifier VGA, and the output power of the variable gain amplifier VGA corresponds to a booster (11) to output a high voltage, so that the electrically adjustable switch (6) of the variable gain amplifier VGA (15) is used for electrically adjusting the switches (6), the power amplifiers (7), (8) and (9), the electrically adjustable switch (10), the booster (11), the voltage reduction circuit (12), the detector (13), the power divider and the operational amplifier (14) form negative feedback. The positive input end of the operational amplifier (14) determines the gain of the variable gain amplifier VGA under the ideal condition according to the level of the reference voltage generated by the singlechip (5), and when the reference voltage is high, the gain of the variable gain amplifier VGA is increased, and conversely, the gain of the variable gain amplifier VGA is decreased. When a reference voltage corresponding to the VGA gain of the variable gain amplifier is set through the singlechip (5) according to requirements, the reference voltage does not change any more, and if the reference voltage is influenced by interference factors such as environment and the like, at the moment, the booster voltage is higher than the set output voltage, the voltage of the negative input end of the operational amplifier (14) is raised inevitably, the original reference voltage generated by the singlechip (5) is not changed, the output voltage uo = A (uid) = A (u + -u-) of the operational amplifier (14) is reduced, the control voltage of the variable gain amplifier VGA (15) is reduced, the output power of the variable gain amplifier VGA (15) is reduced, and the booster voltage is reduced. Similarly, if the output voltage of the booster (11) is lower than the set voltage, the output voltage uo of the operational amplifier (14) will become larger, the control voltage of the variable gain amplifier VGA (15) will become larger, the output power of the variable gain amplifier VGA (15) will become larger, and the booster voltage will rise. Therefore, the negative feedback system ensures the stability of the output voltage of the boosting system, and when the voltage fluctuates up and down due to interference, the system can automatically control the gain of the variable gain amplifier VGA, namely, an automatic gain control system AGC is formed, so that the output voltage is stable and reliable. Note that: the operational amplifier (14) uses its property in the linear amplification region as shown in FIG. 9 below, where u1 is the uid input to our system, and uo becomes larger when u1 becomes larger, and vice versa. Thereby functioning as negative feedback.

The second implementation:

the second embodiment is different from the first embodiment only in that the capacitance of an LC circuit used for input matching, interstage matching and output matching of the power amplifier is changed into a varactor diode, the inductance value is fixed, and the matching resonant frequency is changed by changing the capacitance value only by changing the control voltage of the varactor diode. Since the matching resonant frequency can be changed according to the resonant frequency formula fc = 1/(LC under 2 pi × root) only by changing the capacitance value (where L and C are respectively the small inductance value and capacitance value of all the inductance and capacitance values in the input-output matching network), the Q value (quality factor) of the whole circuit is low, that is, the frequency interference resistance is weak, and the output power efficiency is low compared with the implementation one. Since the latter booster (11) is a high-Q device, the relatively low Q of the power amplifier here is less likely to cause instability of the circuit and interference of excessive harmonics. Therefore, the method for implementing the second embodiment can be implemented in the present boosting system, and the specific circuit diagram is shown in the circuit diagram of fig. 4.

Claims (10)

1. A portable adjustable stable alternating current high voltage generating system comprises a single chip microcomputer (5), and is characterized in that a small computer (16) is connected with the single chip microcomputer (5); the singlechip (5) is respectively connected with the comparator (4), the electric regulation switch A (6), the operational amplifier (14), the phase-locked loop (17), the stepping motor A (18) and the stepping motor B (19); the phase-locked loop (17) is connected with the variable gain amplifier VGA (15); the variable gain amplifier VGA (15) is connected with the electrically-regulated switch A (6); the electric regulation switch A (6) is respectively connected with a power amplifier A (7), a power amplifier B (8) and a power amplifier C (9); the power amplifier A (7), the power amplifier B (8) and the power amplifier C (9) are connected with an electric regulation switch B (10); the electric regulation switch B (10), the stepping motor A (18) and the stepping motor B (19) are connected with the high-voltage booster (11); one end of the high-voltage booster (11) outputs, and the other end of the high-voltage booster is connected with the voltage reduction circuit (12); the voltage reduction circuit (12) is connected with the detector (13); the detector (13) is respectively connected with the comparator (4) and the operational amplifier (14); the operational amplifier (14) is connected with a variable gain amplifier VGA (15); the comparator (4) is respectively connected with the power supply switch (3) and the electric regulation switch A (6); the power supply switch (3) is connected with the rechargeable battery (2) and the power adapter (1); the power adapter (1) is connected with the rechargeable battery (2); the input end of the power adapter (1) is connected with 220V;

the automatic gain control AGC system is formed by a variable gain amplifier VGA, an operational amplifier and a peak detector, the high-voltage booster is stabilized on the voltage corresponding to a certain booster of all amplifiers within the limit output power by setting the level of an output pin of a single chip microcomputer, the system can detect the over-high voltage and the over-low voltage, the input power of a subsequent power amplifier is adjusted by changing the gain of the VGA amplifier of the variable gain amplifier, the output power of the booster corresponding to the output power of the power amplifier is reduced by the AGC system to reduce the final voltage if the output voltage of the booster is larger than the expected value, and vice versa.

2. The portable adjustable stable ac high voltage generation system according to claim 1, wherein the electrically tunable switch a (6), the power amplifier a (7), the power amplifier B (8), the power amplifier C (9), and the electrically tunable switch B (10) form a power amplification circuit, wherein four D Zener diodes in the circuit are Zener diodes, a capacitor C1, a capacitor C2, a capacitor C3, a capacitor C4, a capacitor C5, a capacitor C6, a capacitor C7, a capacitor C8, a capacitor C9, a capacitor C10, a capacitor C11, a capacitor C12, a capacitor C13, a capacitor C14, a capacitor C15, a capacitor C16, a capacitor C17, a capacitor C18, a capacitor C19, a capacitor C20, a capacitor CAP1, a capacitor CAP2, a capacitor CAP3, a capacitor CAP4, an inductor L1, an inductor L2, an inductor L3, an inductor L4, an inductor L5, a resistor R1, a resistor R2, a resistor R3, a resistor R6, a resistor R8, a sliding resistor R4, a varistor R7, a power amplifier Q2, a varistor Q2, and a varistor.

3. The portable adjustable stable alternating current high voltage generation system according to claim 1, wherein the electrically adjustable switch B (10) is connected with a transmission line through an SMA adapter, and then is connected with the high voltage booster (11) through the transmission line, and the input of the high voltage booster (11) is accessed by a coaxial line.

4. The portable adjustable stable alternating-current high-voltage generation system according to claim 1, wherein an input-output matching circuit including a varactor diode is adopted, an original electric-tuning switch a (6) is replaced by an input matching circuit a (20) including a varactor diode, an electric-tuning switch B (10) is replaced by an input matching circuit B (21) including a varactor diode, and the structure is as follows:

the small computer (16) is connected with the singlechip (5); the singlechip (5) is respectively connected with the comparator (4), an input matching circuit A (20) containing a variable capacitance diode, a power amplifier A (7), an operational amplifier (14), a phase-locked loop (17), a stepping motor A (18) and a stepping motor B (19); the phase-locked loop (17) is connected with the variable gain amplifier VGA (15); the variable gain amplifier VGA (15) is connected with an input matching circuit A (20) containing a variable capacitance diode; an input matching circuit A (20) containing a variable capacitance diode is connected with a power amplifier A (7); the power amplifier A (7) is connected with an input/output matching circuit B (21) containing a variable capacitance diode; an input/output matching circuit B (21) containing a variable capacitance diode, a stepping motor A (18) and a stepping motor B (19) are connected with the high-voltage booster (11); one end of the high-voltage booster (11) outputs, and the other end of the high-voltage booster is connected with the voltage reduction circuit (12); the voltage reduction circuit (12) is connected with the detector (13); the detector (13) is respectively connected with the comparator (4) and the operational amplifier (14); the operational amplifier (14) is connected with a variable gain amplifier VGA (15); the comparator (4) is connected with the power supply switch (3); the power supply switch (3) is connected with the rechargeable battery (2) and the power adapter (1); the power adapter (1) is connected with the rechargeable battery (2); the input end of the power adapter (1) is connected with 220V.

5. A portable adjustable stable AC high voltage generation system according to claim 4, characterized in that the input matching circuit A (20) containing varactor diode is connected to the power amplifier A (7); the power amplifier A (7) is connected with an input and output matching circuit B (21) containing a variable capacitance diode to form a power amplifying circuit, wherein four D Zener in the circuit are voltage stabilizing diodes, a capacitor C1, a capacitor C2, a capacitor C3, a capacitor C4, a capacitor C5, a capacitor C6, a capacitor C7, a capacitor C8, a capacitor C9, a capacitor C10, a capacitor C11, a capacitor C12, a capacitor C13, a capacitor C14, a variable capacitance diode D1, a variable capacitance diode D2, a variable capacitance diode D3, a variable capacitance diode D4, a variable capacitance diode D5, a variable capacitance diode D6, a capacitor CAP1, a capacitor CAP2, a capacitor CAP3, a capacitor CAP4, an inductor L1, an inductor L2, an inductor L3, an inductor L4, an inductor L5, a resistor R1, a resistor R2, a resistor R3, a resistor R5, a resistor R6, a resistor R8, a sliding rheostat R4, a sliding rheostat R7, a power amplifier Q1 and a power amplifier Q2.

6. The portable adjustable stable alternating current high voltage generation system according to claim 4, wherein the output end of the input/output matching circuit B (21) containing the varactor diode is connected with a transmission line through an SMA adapter, and then is connected with the high voltage booster (11) through the transmission line, and the input of the high voltage booster (11) is accessed through a coaxial line.

7. The portable adjustable stable ac high voltage generation system according to claim 1 or 4, wherein the single chip microcomputer is an MSP430F438 single chip microcomputer; the single chip microcomputer (5) is connected with a phase-locked loop (17) through a serial port, and the output of an ADF4351 of the phase-locked loop (17) is connected with a variable gain amplifier VGA (15) ADL5331.

8. The portable adjustable stable ac high voltage generation system according to claim 1 or 4, wherein said voltage reduction circuit (12) is composed of two 50K ohm resistors R1 and R2 and one 1:1 balun K1 and one 50 ohm resistor R3.

9. A portable, adjustable, stable AC high voltage generation system according to claim 1 or 4, characterized in that the high voltage booster (11) is: an inductance fixing rod (23) and a plectrum guide rod (27) are fixed in the metal shell (22), and two ends of a plectrum moving rod (28) penetrate through the metal shell (22); an inductor I (24) and an inductor III (26) are wound at two ends of the inductor fixing rod (23), and an inductor II (25) is wound in the middle of the inductor fixing rod; one ends of the first inductor (24), the second inductor (25) and the third inductor (26) are grounded, the other ends of the first inductor (24) and the third inductor (26) are fixed on the inductor fixing rod (23), and the other end of the second inductor (25) is connected with a resistor and an inductor; both ends are connected the metal pole for non-conductive material on plectrum carriage release lever (28), metal pole connecting rod, and non-conductive material is connected to the threaded rod intermediate junction, and each cover has a plectrum (29) on two sections threaded rods, and plectrum (29) below through-hole is run through by plectrum guide bar (27), and coupling nut (30) on the metal pole at plectrum carriage release lever (28) both ends, electricity intercommunication between two nuts (30) is equipped with parallelly connected resistance and electric capacity.

10. The portable adjustable stable alternating current high voltage generation system according to claim 1 or 4, characterized in that the phase-locked loop (17), the stepping motor A (18), the stepping motor B (19), the electric adjusting switch A (6), the electric adjusting switch B (10), the input matching circuit A (20) with the variable capacitance diode and the variable capacitance diode variable capacitance voltage of the input matching circuit B (21) with the variable capacitance diode are all controlled by the singlechip (5), and the variable gain amplifier VGA (15) is indirectly controlled by the reference signal generated by the singlechip through the operational amplifier (14).

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