Microwave generator

A microwave generator comprises a magnetron having an anode and a cathode, oscillating by the current supplied to the anode, and generating a microwave, electric-field controlling means for controlling one of the frequency/phase and the amplitude of the microwave by varying the electric field, and magnetic-field varying means for stabilizing the other by varying the magnetic field.

This application is the U.S. national phase of international application PCT/JP2004/014738, filed 6 Oct. 2004, which designated the U.S. and claims priority of JP 2003-350463, filed 9 Oct. 2003, the entire contents of each of which are hereby incorporated by reference.

TECHNICAL FIELD

The present invention relates to a microwave generating apparatus with a magnetron as an oscillating source.

BACKGROUND ART

As such a microwave generating apparatus, mainly used as a heating apparatus, an apparatus in which a coil is formed around the magnet portion of a magnetron for consumer use, and control of the frequency/phase of a microwave oscillated from the magnetron, is realized by combining control of a magnetic field strength and injection locking (e.g. refer to a patent document 1), and an apparatus in which control of the frequency/phase of a microwave oscillated from the magnetron, is realized by combining phase-locked loop (PLL) with respect to the power supply of the magnetron for commercial use and injection locking (e.g. refer to a patent document 2) are proposed.

Patent document 1: Japanese Patent Application Laying Open NO. Sho 60-123110

Patent document 2: Japanese Patent Application Laying Open NO. 2002-43848

However, in the conventional microwave generating apparatus, as described in the patent documents 1 and 2, a desired characteristic can be obtained with regard to the control of the frequency/amplitude of the microwave; however, it is difficult to control the amplitude of the microwave. Thus, this apparatus is applied only to a heating apparatus. Therefore, in the present circumstances, the conventional microwave generating apparatus cannot be applied to a plasma generating apparatus, a communicating apparatus, a radar apparatus, or the like, in which it is necessary to stabilize or control the amplitude of the microwave of the magnetron, simultaneously with the stabilization or control of the frequency/phase of the microwave of the magnetron.

DISCLOSURE OF INVENTION

OBJECT TO BE SOLVED BY THE INVENTION

It is therefore an object of the present invention to provide a microwave generating apparatus which can stabilize or control the amplitude of the microwave of the magnetron, simultaneously with the stabilization or control of the frequency/phase of the microwave of the magnetron.

A microwave generating apparatus of the present invention is provided with:

a magnetron having an anode and a cathode and oscillating by an electric current supplied to the anode, to thereby generate a microwave;

an electric-field controlling device for controlling at least one of a frequency/phase and an amplitude of the microwave, by changing an electric field; and

a magnetic-field changing device for stabilizing another of the frequency/phase and the amplitude of the microwave, by changing a magnetic field.

Another microwave generating apparatus of the present invention is provided with:

a magnetron having an anode and a cathode and oscillating by an electric current supplied to the anode, to thereby generate a microwave;

an electric-field controlling device for controlling at least one of a frequency/phase and an amplitude of the microwave, by changing an electric field; and

a magnetic-field controlling device for controlling another of the frequency/phase and the amplitude of the microwave, by changing a magnetic field.

According to the microwave generating apparatus of the present invention, at least one of (i) the frequency/phase (i.e., frequency and/or phase) and (ii) the amplitude of the microwave is controlled by changing the electric field, and the other of the frequency/phase and the amplitude of the microwave is stabilized by changing the magnetic field. By this, it is possible to control at least one of the frequency/phase and the amplitude of the microwave, and simultaneously with this, it is possible to stabilize the other of the frequency/phase and the amplitude of the microwave.

According to the another microwave generating apparatus of the present invention, at least one of the frequency/phase and the amplitude of the microwave is controlled by changing the electric field, and the other of the frequency/phase and the amplitude of the microwave is controlled by changing the magnetic field. By this, it is possible to simultaneously control the frequency/phase and the amplitude of the microwave.

Incidentally, the term “stabilize or stabilization” means that the frequency/phase and the amplitude of the microwave as well as the output of the microwave generating apparatus are passively changed so as to include them in a predetermined range. The term “control” means that the frequency/phase and the amplitude of the microwave as well as the output of the microwave generating apparatus are actively changed from the exterior.

Preferably, it is further provided with: an injection locking device for controlling the frequency/phase of the microwave, by injecting a reference signal, which has a natural frequency close to a natural oscillation frequency of the magnetron, into the magnetron, drawing an oscillation frequency of the magnetron into the frequency of the reference signal, and locking the oscillation frequency of the magnetron.

BEST MODE FOR CARRYING OUT THE INVENTION

Hereinafter, embodiments of the microwave generating apparatus of the present invention will be discussed in detail, with reference to the drawings. In the drawings, the same constitutional elements carry the same numerical reference.

FIG. 1is a diagram showing a first embodiment of the microwave generating apparatus of the present invention. This microwave generating apparatus is provided with: a magnetron1; a high-voltage direct current stabilized power supply2; a directional coupler3; an attenuator—phase or amplitude regulator (i.e., “attenuator” and “phase or amplitude regulator”)4; a phase or amplitude comparator5; a reference signal generator6; and a variable phase shifter7.

Between an anode (positive electrode) and a cathode (negative electrode) of the magnetron1, which are not illustrated, a high-voltage direct current (hereinafter referred to as an “anode current”) is flown from the high-voltage direct current stabilized power supply2. By this, the magnetron1is set in an oscillation state. A microwave radiated from the magnetron1is outputted to the exterior through the directional coupler3. For example, it is transmitted to an electric supply system, such as a horn antenna.

The directional coupler3divergingly outputs one portion of the microwave output to the attenuator—phase or amplitude regulator4. The diverged output is attenuated and is phase or amplitude-regulated, and is then supplied to the phase or amplitude comparator5.

The reference signal generator6generates a reference signal which has a frequency close to the natural oscillation frequency of the magnetron1, and the generated reference signal is supplied to the phase or amplitude comparator5through the variable phase shifter7.

The phase or amplitude comparator5compares the microwave with the reference signal, with regard to at least one of the frequency/phase and the amplitude, and changes the anode current such that at least one of the frequency/phase and the amplitude of the microwave matches that of the reference signal, in accordance with a result of the comparison. By this, at least one of the control of the frequency/phase and the stabilization of the amplitude of the microwave is controlled by a change in an electric field.

Along with this, at least the other of the frequency/phase and the amplitude of the microwave is stabilized, due to a passive change in a magnetic field, by manually changing the current of a not-illustrated coil, which is formed around a not-illustrated magnet of the magnetron1. As a result, according to this embodiment, at least one of the frequency/phase and the amplitude of the microwave is controlled by phase-locked loop (PLL) feedback to the power supply, and simultaneously with this, by changing the current flowing to the coil, the other of the frequency/phase and the amplitude of the microwave can be controlled.

FIG. 2is a diagram showing a second embodiment of the microwave generating apparatus of the present invention. This microwave generating apparatus is provided with: the magnetron1; the high-voltage direct current stabilized power supply2; a directional coupler3′; the attenuator—phase or amplitude regulator4; the phase or amplitude comparator5; the reference signal generator6; the variable phase shifter7; and a phase or amplitude comparator8.

In this embodiment, the directional coupler3′ also divergingly outputs one portion of the microwave output to the phase or amplitude comparator8, in addition to the attenuator—phase or amplitude regulator4. The reference signal is also supplied to the phase or amplitude comparator8. The phase or amplitude comparator8compares the microwave with the reference signal, with regard to intensity, and actively changes the current of a not-illustrated coil such that the intensity of the microwave matches that of the reference signal, in accordance with a result of the comparison. By this, at least the other of the control of the frequency/phase and the stabilization of the amplitude of the microwave is controlled by a change in an electric field. By this, it is possible to simultaneously control the frequency/phase and the amplitude of the microwave.

FIG. 3is a diagram showing a third embodiment of the microwave generating apparatus of the present invention. This microwave generating apparatus is provided with: the magnetron1; the high-voltage direct current stabilized power supply2; the directional coupler3; the attenuator—phase or amplitude regulator4; the phase or amplitude comparator5; the reference signal generator6; the variable phase shifter7; a distributor9; and a circulator10.

In this embodiment, the reference signal is supplied to the distributor9through the variable phase shifter7. The distributor9distributes the inputted reference signal into two systems, such that the reference signal in one system is supplied to the circulator10and the reference signal in the other system is supplied to the phase or amplitude comparator5.

In the circulator10, the reference signal supplied from the distributor9is inputted from a first terminal, and the inputted reference signal is outputted from a second terminal, to thereby inject it into the magnetron1. Then, the microwave radiated from the magnetron1is taken into the circulator10from the second terminal, and outputted from a third terminal. The microwave outputted from the circulator10is outputted to the exterior through the directional coupler3. For example, it is transmitted to an electric supply system, such as a horn antenna.

In the oscillation state of the magnetron1, the reference signal, which has a frequency close to the natural oscillation frequency of the magnetron1and which is generated on the reference signal generator6, is injected into the magnetron1through the circulator10. As a result, the oscillation frequency of the magnetron1is drawn into the frequency of the reference signal.

The microwave radiated from the magnetron1is outputted to the exterior through the circulator10and the directional coupler3. At this time, because of the characteristics that the circulator10has, the microwave output does not return to the reference signal input side.

According to this embodiment, at least one of the frequency/phase and the amplitude of the microwave is controlled by the PLL feedback with respect to the power supply, and simultaneously with this, by changing the current flowing to the coil, the other of the frequency/phase and the amplitude of the microwave can be stabilized. Moreover, by virtue of the injection locking, it is possible to draw the oscillation frequency of the magnetron1into the frequency of the reference signal, and lock (i.e., achieve synchronization of) the frequency/phase by the feedback control. At this time, the frequency/phase are locked by controlling the anode current of the magnetron1, so that it is possible to take an extremely broad control range or width, which further improves the stabilization.

FIG. 4is a diagram showing a fourth embodiment of the microwave generating apparatus of the present invention. This microwave generating apparatus is provided with: the magnetron1; the high-voltage direct current stabilized power supply2; the directional coupler3; the attenuator—phase or amplitude regulator4; the phase or amplitude comparator5; the reference signal generator6; the variable phase shifter7; the phase or amplitude comparator8; the distributor9; and the circulator10.

According to this embodiment, it is possible to simultaneously control the frequency/phase and the amplitude of the microwave, and further improve the stabilization.

FIGS. 5are diagrams showing experimental results in a conventional microwave generating apparatus.FIGS. 6are diagrams showing experimental results in the microwave generating apparatus of the present invention. Incidentally, as the conventional microwave generating apparatus, an apparatus which does not change the current of the coil of the magnetron1in the microwave generating apparatus shown inFIG. 1was used. As the microwave generating apparatus of the present invention, the microwave generating apparatus shown inFIG. 3was used.

In the conventional microwave generating apparatus, it can be seen that even if a phase difference is set within about 10 degrees for 50 seconds as shown inFIG. 5A, an output power changes by about 40 W as shown inFIG. 5B.

As opposed to this, in the microwave generating apparatus of the present invention, it can be seen that even if the current of the coil of the magnetron1is increased (FIG. 6D) so as to increase the output power from 450 W to 500 W for 10 to 15 seconds (FIG. 6B), and in response to that, a cathode current control voltage increases from 6.5V to 7V (FIG. 6C), the phase difference is stable in a condition of zero after 25 seconds.

The present invention is not limited to the above-described embodiments, and various changes and modifications can be made. For example, in the above-mentioned embodiments, the electric field is changed by the PLL feedback with respect to the power supply, and the magnetic field is changed by actively or passively changing the current of the coil; however, the change in the electric field and the change in the magnetic field can be performed in other arbitrary methods.

INDUSTRIAL APPLICABILITY

In the present invention, it is possible to stabilize or control the amplitude of the microwave of the magnetron, simultaneously with the stabilization or control of the frequency/phase of the microwave of the magnetron. Thus, it is possible to inexpensively construct not only a heating apparatus but also various apparatuses which use a microwave for communication use or for energy transmission use (e.g. a plasma generating apparatus, a communicating apparatus, and a radar apparatus), in which it is necessary to stabilize or control the amplitude of the microwave of the magnetron, simultaneously with the stabilization or control of the frequency/phase of the microwave of the magnetron.