JP3098365U - AM broadcast receiver - Google Patents

Abstract

A beat failure caused by switching noise is removed even when a self-excited switching power supply is used.
Kind Code: A1 A beat failure that occurs when a receiving unit receives an AM broadcast due to harmonic noise that is a switching noise having a frequency that is an integral multiple of a switching frequency of a self-excited switching power supply is reduced by a switching frequency. A beat elimination unit that removes the beat by changing it; a beat elimination key to which a user operation is input; a load resistor R1 serving as a load of a DC output of the self-excited switching power supply 4; And a switch unit 5 for opening and closing the connection of the current path. When the beat removal key is operated, the connection state of the switch unit 5 is reversed.
[Selection diagram] Fig. 1

Description

[0001]
[Technical field to which the invention belongs]
The present invention relates to an AM broadcast receiving apparatus whose operating power is supplied from a self-excited switching power supply. More specifically, when a beat failure occurs, the switching frequency of the self-excited switching power supply is changed to eliminate the beat failure. The present invention relates to an AM broadcast receiving device.
[0002]
[Prior art]
In a device that receives AM broadcasts in the medium-wave band, when operating power is supplied from a switching power supply, harmonic noise having a frequency that is an integral multiple of the switching frequency of the switching power supply has a frequency close to the frequency of the AM broadcast to be received. Sometimes. In such a case, a beat occurs between the harmonic noise and the carrier of the AM broadcast to be received, and the broadcast becomes very hard to hear. In order to solve such inconvenience, the following related art has been proposed (hereinafter referred to as a first related art). That is, in this technique, a separately excited switching power supply is provided with two oscillation circuits for determining a switching frequency. The oscillation frequencies of the two oscillation circuits are different from each other. Then, one of the two oscillation circuits is selected according to the frequency of the AM broadcast to be received. Therefore, in the case where the oscillation circuit on one side is used, even when a beat failure occurs, the occurrence of the beat failure is avoided by using the other side (for example, see Patent Document 1).
[0003]
Further, the following related art has been proposed (hereinafter referred to as a second related art). That is, in this technique, a signal obtained by dividing the local oscillation signal of the receiving unit that receives the AM broadcast by half is used as a signal for switching. Therefore, the switching frequency and a frequency that is an integral multiple of the switching frequency are far away from the frequency to be received, so that occurrence of a beat failure in AM broadcast reception can be avoided (for example, see Patent Document 2).
[0004]
[Patent Document 1]
Japanese Patent No. 2684862
[Patent Document 2]
Japanese Patent No. 3276921
[0005]
[Problems to be solved by the invention]
However, the first prior art and the second prior art are techniques applicable when a separately-excited switching power supply that can determine a switching frequency by an oscillation frequency of an oscillation circuit is used. On the other hand, in an RCC type switching power supply having a simple circuit configuration and a low component cost, the switching frequency is not constant but changes according to the state of the load. For this reason, it has been difficult to apply this method when using an RCC switching power supply for generating an operation power supply.
[0006]
The present invention has been made in order to solve the above-mentioned problem, and an object of the present invention is to eliminate a beat disturbance caused by switching noise even when an RCC switching power supply is used, and to realize a beat disturbance. It is an object of the present invention to provide an AM broadcast receiving apparatus capable of suppressing an increase in power consumption caused by removing the noise to a very small value and preventing an unnecessary increase in power consumption.
[0007]
Another object of the present invention is to change the switching frequency by changing the load of the self-excited switching power supply when a beat failure occurs at the time of receiving the AM broadcast, thereby using the self-excited switching power supply. An object of the present invention is to provide an AM broadcast receiving apparatus capable of removing a beat failure caused by noise.
[0008]
In addition to the above purpose, the signal is an integer multiple of the switching frequency, and the amount of change when changing the frequency of harmonic noise that interferes with the received broadcast is 1.5 times the minimum value of the interval between broadcast frequencies. An object of the present invention is to provide an AM broadcast receiving apparatus capable of suppressing an increase in power consumption caused by removing a beat fault to a very small value by setting the value to twice the range.
[0009]
In addition to the above-mentioned object, the amount of the transition when the frequency of the harmonic noise that interferes with the received broadcast is a signal that is an integral multiple of the switching frequency is changed from twice to five times the minimum value of the broadcast frequency interval. It is therefore an object of the present invention to provide an AM broadcast receiving apparatus capable of stably removing a beat failure while suppressing an increase in power consumption caused by removing the beat failure by setting the value in the range of.
[0010]
[Means for Solving the Problems]
In order to solve the above problems, an AM broadcast receiving apparatus according to the present invention includes a receiving unit that receives an AM broadcast, a switching power supply that supplies operating power to the receiving unit, and switching noise having a frequency that is an integral multiple of the switching frequency of the switching power supply. The present invention is applied to an AM broadcast receiving apparatus having a beat removing unit that removes a beat failure that occurs when a receiving unit receives an AM broadcast due to a higher harmonic noise by changing a switching frequency of a switching power supply. are doing. The switching power supply is an RCC switching power supply, and the beat removing means includes a beat removal key to which a user operation is input, a load resistor serving as a load of a DC output of the RCC switching power supply, and a beat resistor inserted into a current path of the load resistor. And a switch unit for opening and closing the connection of the current path. When the beat removal key is operated, the connection state of the switch unit is reversed, and the reception unit receives the AM broadcast when the connection of the switch unit is closed. When the frequency is changed, the connection of the switch section is opened, and the value of the load resistance is changed by opening the connection of the switch section for the harmonic noise whose frequency is the lowest frequency in the medium frequency band among the harmonic noise. The difference between the frequency when the switch is closed and the frequency when the switch is closed is the minimum It is set to a value that is twice the range of .5 times.
[0011]
That is, when the connection of the switch unit is reversed, the total power consumption changes by the power consumption due to the load resistance. Therefore, the switching frequency of the RCC switching power supply changes. In addition, since the amount of change of the harmonic noise is small, the power consumption of the load resistor required for changing the frequency of the harmonic noise remains at a very small value. Further, when the state shifts from receiving an AM broadcast having a frequency causing a beat failure to receiving an AM broadcast having a different frequency, power consumption by the load resistance is stopped.
[0012]
The AM broadcast receiving apparatus according to the present invention includes a receiving unit that receives an AM broadcast, a switching power supply that supplies operating power to the receiving unit, and a harmonic noise that is a switching noise having a frequency that is an integral multiple of the switching frequency of the switching power supply. Is applied to an AM broadcast receiving apparatus having a beat removing unit that removes a beat failure that occurs when the receiving unit receives an AM broadcast by changing a switching frequency of a switching power supply. The switching power supply is a self-excited switching power supply, and the beat removing means is inserted into a beat removal key to which a user operation is input, a load resistance serving as a DC output load of the self-excited switching power supply, and a current path of the load resistance. A switch for opening and closing the connection of the current path, and when the beat removal key is operated, the connection state of the switch is reversed.
[0013]
That is, when the connection of the switch unit is reversed, the total power consumption changes by the power consumption due to the load resistance. Therefore, the switching frequency of the self-excited switching power supply changes.
[0014]
In addition to the above configuration, the value of the load resistance is the frequency of the harmonic noise whose frequency is the lowest frequency in the medium-wave band among the harmonic noise, when the connection of the switch is opened and the frequency of the switch. Is set to a value that is in the range of 1.5 to 2 times the minimum value of the interval of the frequency of AM broadcast in the medium frequency band. That is, since the amount of change of the harmonic noise is small, the power consumption of the load resistor necessary for changing the frequency of the harmonic noise remains at a very small value.
[0015]
In addition to the above configuration, the value of the load resistance is the frequency of the harmonic noise whose frequency is the lowest frequency in the medium-wave band among the harmonic noise, when the connection of the switch is opened and the frequency of the switch. Is set to a value that is in the range of twice to five times the minimum value of the frequency interval of the AM broadcast frequency in the medium frequency band. That is, since the amount of change of the harmonic noise is relatively small, the power consumed by the load resistor to change the harmonic noise can be set to a relatively small value. Also, when a drift occurs in the switching frequency (a drift occurs in the harmonic noise), a sufficient difference is secured between the frequency of the AM broadcast being received and the frequency of the harmonic noise.
[0016]
[Embodiment of the invention]
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing an electrical configuration of an integrated DVD playback device / video cassette recorder receiving device to which an embodiment of an AM broadcasting receiving device according to the present invention is applied.
[0017]
In FIG. 1, a DVD reproducing unit 1 reproduces a DVD (not shown) and outputs a video signal and an audio signal obtained by the reproduction to an output switching unit 6. The video cassette recorder unit 2 reproduces the video cassette tape and outputs a video signal and an audio signal obtained by the reproduction to the output switching unit 6. In addition, a video signal and an audio signal are recorded on a video cassette tape. The receiving section 3 receives AM broadcasts and FM broadcasts in the medium frequency band, and outputs the received audio signals to the output switching section 6. In accordance with an instruction from the control unit 7, the output switching unit 6 outputs a video signal or an audio signal output from the DVD playback unit 1, a video signal or an audio signal output from the video cassette recorder unit 2, or a reception unit 3. Is output to an output unit (not shown) for displaying video and outputting audio.
[0018]
The input unit 8 includes a plurality of key switches (not shown) such as a power key provided on a front panel, a receiving unit that receives an infrared signal transmitted from the remote controller 9, and the like. Is entered. The input instruction is sent to the control unit 7. As shown in FIG. 3, the remote controller 9 includes a power key 30, a numeric key 31, and the like. Also, when a beat disturbance occurs while receiving an AM broadcast, a beat removal key 32 operated by a user for removing the beat disturbance is provided.
[0019]
The RCC switching power supply (hereinafter simply referred to as a switching power supply) 4 has a configuration known as a conventional technique, and supplies operating power to the receiving unit 3. The operating power is also supplied to the DVD reproducing unit 1, the video cassette recorder unit 2, the output switching unit 6, and the control unit 7. Note that the switching frequency when the receiving unit 3 is in a state of receiving AM broadcast is about 90 KHz. The load resistor R1 is an element that forms a load of the DC output of the switching power supply 4. The switch unit 5 is a block that opens and closes the connection of the current path of the load resistor R1.
[0020]
FIG. 2 is a circuit diagram showing the electrical connection of the switching power supply 4, the load resistor R1, and the switch unit 5. The configurations of the switching power supply 4, the load resistor R1, and the switch unit 5 will be described in detail with reference to FIG.
[0021]
The switching circuit 21 is a block that switches the current flowing through the primary coil L1 wound around the transformer 22 by performing self-excited oscillation. For this reason, the output of the feedback coil L3 is guided to the gate, and a self-excited oscillation is provided to provide a switching FET for switching the current flowing through the primary coil L1. Further, a control transistor for controlling the switching of the switching FET by controlling the gate potential of the switching FET in accordance with the output of the photocoupler 26 is provided.
[0022]
The error detection circuit 25 detects the voltage error of the DC output V5 of 5 V obtained by rectifying and smoothing the output of the tap of the secondary coil L2 with the diode D2 and the capacitor C2. It returns to the switching circuit 21.
[0023]
The diode D1 and the capacitor C1 rectify and smooth the output of the end terminal of the secondary coil L2 to generate a DC output V12 of 12V. The constant voltage switch circuit 23 is a step-down constant voltage circuit that generates a DC output V9P stabilized at 9V from a DC output V12 of 12V. In addition, the voltage of the DC output V9P is switched between 9V and 0V according to the output 52 from the control unit 7. The switch circuit 24 is a block for turning on and off the DC output V5 of 5V. When the DC output V9P is 9V, the voltage of the DC output V5P is 5V, and when the DC output V9P is 0V, the voltage of the DC output V5P. Is set to 0V.
[0024]
That is, the DC outputs V5P and V9P become 5V and 9V when the power is turned on using the power key 30, and become 0V when the power is turned off. Therefore, the DC outputs V5P and V9P are supplied as operating power to the DVD reproducing unit 1, the video cassette recorder unit 2, the receiving unit 3, and the output switching unit 6. The DC output V5, which is always maintained at 5V, is an operating power supply for the control unit 7. The DC output V12 is supplied to a block that requires an operation power supply even when the power is turned off (for example, a display circuit that displays time or the like even when the power is turned off). Although other DC outputs are also generated, these are not shown.)
[0025]
The resistor R1 is a load resistor serving as a load for the DC output V12. Therefore, one terminal of the load resistor R1 is connected to the DC output V12. The other terminal is connected to the collector of the transistor Q1. Further, an output 53 from the control unit 7 is guided to the base of the transistor Q1 via a resistor R2 for limiting a base current. The emitter of the transistor Q1 is grounded, and a resistor R3 for suppressing an increase in the base impedance is connected between the base and the ground level.
[0026]
The switch unit 5 including the two resistors R2 and R3 and the transistor Q1 has the above-described configuration. Therefore, when the output 53 goes high, the connection of the current path of the load resistor R1 is closed, and when the output 53 goes low, the connection of the current path of the load resistor R1 is opened.
[0027]
Here, the switching frequency of the switching circuit 21 will be described. When the load on the secondary side increases, the switching frequency decreases, and when the load decreases, the switching frequency increases. Therefore, when the connection of the switch section 5 is closed and the connection of the current path of the load resistor R1 is closed, the switching frequency is reduced in accordance with the increase in load due to the load resistor R1. That is, the switching frequency of the switching circuit 21 can be changed by opening and closing the connection of the switch unit 5. The power consumed by the load resistor R1 is wasted power. For this reason, the value of the load resistor R1 is set so that power consumption is reduced as much as possible (described later).
[0028]
Returning to the description of the overall configuration with reference to FIG. The control section 7 is mainly composed of a microcomputer, and controls the main operation of the DVD-reproducing apparatus / video cassette recorder integrated receiving apparatus. Therefore, the operation of the DVD reproducing unit 1 is controlled. Further, the operation of the video cassette recorder 2 is controlled. Also, it controls the frequency received by the receiving unit 3 and the like.
[0029]
Further, the control unit 7 constitutes a beat removing unit by cooperating with the load resistor R1 and the switch unit 5. That is, the switching noise (hereinafter, referred to as harmonic noise) having an integral multiple of the switching frequency of the switching power supply 4 becomes a frequency close to the frequency of the AM broadcast received by the receiving unit 3, so that the received AM When a beat failure occurs in the broadcast, the above-mentioned beat failure is eliminated by changing the switching frequency of the switching power supply 4.
[0030]
In other words, when the input unit 8 notifies that the beat removing key 32 has been operated while the receiving unit 3 is receiving the AM broadcast in the medium frequency band, the control unit 7 switches the connection of the switch unit 5. Invert the state. As a result, the switching frequency of the switching power supply 4 changes, so that the frequency of the harmonic noise shifts from the frequency at which the beat failure occurs to a slightly different frequency, and the beat failure disappears.
[0031]
When the user instructs to change the frequency of the AM broadcast received by the receiving unit 3, the control unit 7 controls the receiving unit 3 to receive the AM broadcast of the designated frequency. Further, when the connection of the switch unit 5 is closed, unnecessary power consumption is stopped by changing the connection of the switch unit 5 to the open state (when the connection of the switch unit 5 is already open). Sometimes, keep this state).
[0032]
FIG. 4 is an explanatory diagram showing a relationship between an AM broadcast radio wave and harmonic noise. The relationship between the frequency of the harmonic noise and the beat disturbance will be described with reference to FIG.
[0033]
Reference numeral 61 in the figure denotes a carrier signal of an AM broadcast radio wave. Reference numeral 62 denotes a sideband of an AM broadcast radio wave. Note that the minimum value of the frequency interval of AM broadcasting in Japan (hereinafter, referred to as the minimum value) is 9 KHz. For this reason, the spread width d1 of the frequency of the sideband 62 is about 9 KHz.
[0034]
Now, it is assumed that the harmonic noise is a signal indicated by 641. In this case, a beat failure occurs due to interference with the carrier signal 61. When the beat disturbance occurs, when the frequency of the harmonic noise 641 is shifted to make the harmonic noise a signal indicated by, for example, 642, the beat disturbance disappears.
[0035]
Here, when a beat disturbance due to harmonic noise occurs, the frequency width that needs to be shifted will be discussed with reference to FIG. When the frequency of the harmonic noise is shifted to the lower side to remove the beat interference, the harmonic noise under the worst condition is when the signal indicated by 631 is obtained. Even at this time, if the amount of frequency shift is 1.5 times the minimum interval value (13.5 KHz), the difference between the frequency of the harmonic noise 632 shifted to the lower side and the carrier signal 61 is a sufficiently large value. And the beat failure disappears.
[0036]
FIG. 7B shows a case where the amount of the above-mentioned change in the frequency of the harmonic noise is set to twice the minimum interval value (18 KHz), and the beat disturbance is removed with a sufficient margin. It is shown.
[0037]
On the other hand, in order to shift the frequency of the harmonic noise to the lower side, it is necessary to shift the switching frequency of the switching power supply 4 to the lower side, and it is necessary to increase the load. Therefore, in order to increase the amount of change in harmonic noise, it is necessary to increase the power consumption of the load resistor R1. On the other hand, when the amount of transition is increased, the drift amount of the harmonic noise 633, 643 also drifts to the higher frequency side due to the drift toward the higher switching frequency after the transition. When the frequency stays at about several KHz, a sufficient difference is secured between the frequency of the harmonic noises 633 and 643 and the frequency of the carrier signal 61, and the effect that no beat failure occurs is obtained.
[0038]
When the amount of change in the switching frequency is constant, the amount of change in the frequency decreases as the harmonic noise becomes a lower-order harmonic signal. Therefore, among the harmonic noises belonging to the medium-wave band, when the required amount of displacement is given to the harmonic noise having the lowest frequency, a sufficient amount of displacement is secured for the harmonic noise of other frequencies. Will be done.
[0039]
From the above, in the embodiment, when the connection of the switch unit 5 is closed at the lowest harmonic noise (about 540 KHz) of the harmonic noise whose frequency is in the middle-wave band, about 15 KHz The value of the load resistor R1 is set such that the frequency shift of the load resistance R1 occurs. At this time, the value of the load resistor R1 is determined experimentally, and the power consumption by the determined value of the load resistor R1 is about 1% of the entire power consumption (drift of the switching frequency). When the connection of the switch unit 5 is closed in the above-described harmonic noise on the lowest frequency side, the load is changed so that a change of 2 to 5 times the minimum interval value occurs. The value of the resistor R1 can also be set).
[0040]
FIG. 5 is a flowchart showing the main operation of the embodiment. The operation of the embodiment will be described with reference to FIG.
[0041]
When the reception mode of the AM broadcast is set (at this time, the connection of the switch unit 5 is open), the control unit 7 controls the reception unit 3 to receive the AM broadcast in the medium frequency band. (Step S1). At this time, it is assumed that a beat failure occurs because the frequency of the received AM broadcast is very close to a frequency (harmonic noise frequency) that is an integral multiple of the switching frequency of the switching power supply 4. It is also assumed that the user operates the beat removal key 32.
[0042]
When notified by the input unit 8 that the beat removal key 32 has been operated, the control unit 7 reverses the connection state of the switch unit 5. That is, the state of the switch unit 5 is changed from the open state to the closed state (steps S2 and S3). When the connection state of the switch unit 5 changes from the open state to the closed state, the overall load of the switching power supply 4 becomes heavier by the load of the load resistor R1, and the switching frequency shifts to a slightly lower side. . As a result, as described above, since the frequency of the harmonic noise shifts to a lower side, the beat disturbance disappears.
[0043]
In this state, when the beat removal key 32 is operated again, the connection of the switch unit 5 is opened again. When the beat removal key 32 is further operated, the connection of the switch unit 5 is closed again. Therefore, the user can easily confirm the effect of removing the beat failure using the beat removal key 32.
[0044]
Now, it is assumed that the connection of the switch unit 5 is closed because the beat removal key 32 is operated. In this state, when an instruction to receive a different frequency is input to the remote controller 9, the control unit 7 controls the receiving unit 3 to receive the AM broadcast of the specified frequency (steps S4 and S5). At the same time, the connection of the switch unit 5 is opened (step S6).
[0045]
The connection of the switch unit 5 is opened in step S6 for the following reason. That is, the reception frequency is changed and the connection of the switch unit 5 is opened, and the reception frequency is changed and the connection of the switch unit 5 is closed. The probability of a beat failure occurring after a frequency change does not change. For this reason, opening the connection of the switch unit 5 eliminates power consumption by the load resistor R1 and can reduce overall power consumption.
[0046]
Note that the present invention is not limited to the above embodiment, and has been described for a case where the present invention is applied to an area where the minimum value of the frequency interval (minimum interval value) in AM broadcasting is 9 KHz. Can be similarly applied.
[0047]
The DC output to which the load resistor is connected has been described as being a 12V DC output V12. However, a configuration in which the DC output is connected to a DC output of another voltage (for example, a 9V DC output V9P or the like) may be adopted. it can.
[0048]
[Effect of the invention]
As described above, the present invention includes a load resistor serving as a load for the DC output of the RCC switching power supply, and a switch section inserted into the current path of the load resistor and opening and closing the connection of the current path. Is operated, the connection state of the switch unit is reversed, and when the frequency of the AM broadcast received by the reception unit is changed, the connection of the switch unit is opened. In addition, the value of the load resistance is the frequency of the harmonic noise whose frequency is the lowest frequency in the medium-wave band among the harmonic noise, when the connection of the switch is opened and the connection of the switch is closed. Is set to a value that is in the range of 1.5 to 2 times the minimum value of the frequency interval of AM broadcast in the medium frequency band. Therefore, when the connection state of the switch section is reversed, the switching frequency of the RCC switching power supply changes. In addition, the power consumption of the load resistor required for changing the frequency of the harmonic noise has a very small value. Further, when the state shifts from receiving an AM broadcast having a frequency causing a beat failure to receiving an AM broadcast having a different frequency, power consumption by the load resistance is stopped. Therefore, even when the RCC switching power supply is used, it is possible to eliminate a beat failure caused by switching noise, and to suppress an increase in power consumption caused by removing the beat failure to a very small value. And unnecessary increase in power consumption can be prevented.
[0049]
Also, in the present invention, a load resistor serving as a load of the DC output of the self-excited switching power supply, and a switch portion inserted into the current path of the load resistor and opening and closing the connection of the current path are provided, and when the beat removal key is operated, , The state of connection of the current path by the switch unit is inverted. Therefore, when the connection of the switch section is reversed, the total power consumption changes by the power consumption due to the load resistance, so that the switching frequency of the self-excited switching power supply changes. Therefore, even when a self-excited switching power supply is used, beat disturbance caused by switching noise can be eliminated.
[0050]
Further, the value of the load resistance is determined based on the frequency of the harmonic noise whose frequency is the lowest frequency in the medium-wave band among the harmonic noise when the connection of the switch is opened and the connection of the switch. The difference from the frequency at the time of closing is set to a value in a range of 1.5 to 2 times the minimum value of the interval of the frequency of the AM broadcast in the medium frequency band. Therefore, the power consumption of the load resistor required for the change of the frequency of the harmonic noise becomes a very small value, so that the increase in the power consumption caused by removing the beat disturbance can be suppressed to a very small value.
[0051]
Further, the value of the load resistance is determined based on the frequency of the harmonic noise whose frequency is the lowest frequency in the medium-wave band among the harmonic noise when the connection of the switch is opened and the connection of the switch. The difference from the frequency at the time of closing is set to a value in the range of 2 to 5 times the minimum value of the interval of the frequency of AM broadcast in the medium frequency band. Therefore, the power consumption due to the load resistance can be set to a relatively small value. Also, a sufficient difference is always ensured between the frequency of the AM broadcast being received and the frequency of the harmonic noise. For this reason, it is possible to stably remove the beat failure while suppressing an increase in power consumption that occurs for removing the beat failure.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an electrical configuration of an integrated DVD playback apparatus / video cassette recorder receiving apparatus to which an embodiment of an AM broadcasting receiving apparatus according to the present invention is applied.
FIG. 2 is a circuit diagram showing an electrical connection of a switching power supply, a load resistor, and a switch unit.
FIG. 3 is an explanatory diagram showing a beat removal key provided in a remote controller.
FIG. 4 is an explanatory diagram showing a relationship between radio waves of AM broadcasting and harmonic noise.
FIG. 5 is an explanatory diagram showing main operations of the embodiment.
[Explanation of symbols]
3 Receiver
4 RCC switching power supply
5 Switch section
32 beat removal key
R1 load resistance

Claims (4)

A receiving unit for receiving an AM broadcast,
A switching power supply for supplying operating power to the receiving unit;
By changing the switching frequency of the switching power supply, it is possible to eliminate beat disturbances that occur when the receiver receives AM broadcasts due to harmonic noise that is a switching noise that is an integer multiple of the switching frequency of the switching power supply. An AM broadcast receiving apparatus having a beat removing unit that performs
The switching power supply is an RCC switching power supply,
Beat removal means
A beat removal key for inputting a user operation,
A load resistance serving as a load of the DC output of the RCC switching power supply,
A switch unit that is inserted into the current path of the load resistance and opens and closes the connection of the current path.
When the beat removal key is operated, the connection state of the switch section is inverted, and when the frequency of the AM broadcast received by the receiving section is changed in a state where the connection of the switch section is closed, the connection of the switch section is opened,
The value of the load resistance is the frequency of the harmonic noise whose frequency is the lowest frequency in the medium frequency band when the connection of the switch is opened and when the connection of the switch is closed. The AM broadcast receiving apparatus is characterized in that a difference from the frequency of the AM broadcast is set to a value which is in a range of 1.5 to 2 times a minimum value of a frequency interval of the AM broadcast in the medium frequency band. A receiving unit for receiving an AM broadcast,
A switching power supply for supplying operating power to the receiving unit;
By changing the switching frequency of the switching power supply, it is possible to eliminate beat disturbances that occur when the receiver receives AM broadcasts due to harmonic noise that is a switching noise that is an integer multiple of the switching frequency of the switching power supply. An AM broadcast receiving apparatus having a beat removing unit that performs
The switching power supply is a self-excited switching power supply,
Beat removal means
A beat removal key for inputting a user operation,
A load resistance serving as a DC output load of the self-excited switching power supply,
A switch unit that is inserted into the current path of the load resistance and opens and closes the connection of the current path.
An AM broadcast receiving apparatus characterized in that when a beat removal key is operated, the connection state of the switch section is inverted. The value of the load resistance is the frequency of the harmonic noise whose frequency is the lowest frequency in the medium frequency band among the harmonic noise when the connection of the switch is opened and when the connection of the switch is closed 3. The AM broadcast according to claim 2, wherein the difference from the frequency of the AM broadcast is set to a value in a range of 1.5 to 2 times the minimum value of the frequency interval of the AM broadcast in the medium frequency band. Receiver. The value of the load resistance is the frequency of the harmonic noise whose frequency is the lowest frequency in the medium frequency band among the harmonic noise when the connection of the switch is opened and when the connection of the switch is closed 3. The AM broadcast receiving apparatus according to claim 2, wherein the difference from the frequency is set to a value which is in a range of 2 to 5 times a minimum value of a frequency interval of the AM broadcast in the medium wave band. .

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