JPH0346601Y2 - - Google Patents

Description

[Detailed Description of the Invention] <Technical Field of the Present Invention> The present invention relates to a reception status display device for a radio receiver.

<Background Art> In general, when receiving FM broadcasts in particular with a radio receiver, the extent to which noise such as multipath is received is determined simply by the reproduced sound, or by being equipped with a multipath terminal or a multipath meter. Both of these methods are impractical, and especially when making judgments based on reproduced sound, it is difficult and inconvenient to position the antenna in the optimum direction.

<Purpose of the present invention> The present invention was devised in view of the drawbacks of the conventional devices mentioned above, and uses the output of an intermediate frequency amplifier to indicate the presence or absence of broadcast radio waves and to detect whether or not they are receiving noise such as multipath. It is an object of the present invention to provide a display device that can perform the above display with an extremely simple configuration.

<Configuration of the present invention> An embodiment of the present invention will be described in detail below with reference to the accompanying drawings.

FIG. 1 is a block electrical circuit diagram of an FM radio receiver equipped with an embodiment of the reception status display device according to the present invention, in which 1 is an antenna, 2 is a front end, 3 is an intermediate frequency filter, and 4 5 is an intermediate frequency amplifier, 5 is an FM detection circuit, and 6 is a stereo signal demodulation circuit.

Reference numeral 7 indicates a display device portion according to the present invention, the details of which are shown in FIG.

In this display device section, 8 and 9 are well-known signal meter circuits and tuning meter circuits connected to the intermediate frequency amplifier 4 and FM detection circuit 5, respectively, and are used to generate a signal indicating the radio field intensity and a tuning point (0
point).

10 is an amplitude modulation component detection circuit which is connected to the intermediate frequency amplifier 4 and receives a signal from the intermediate frequency amplifier 4 in the same way as the signal meter circuit 8;
It consists of D ₁ and D ₂ and capacitors C ₁ and C ₂ , and is designed to detect the amplitude modulation component (noise component accompanying multipath) obtained from the intermediate frequency amplifier 4.

Reference numeral 11 designates an amplifier circuit for amplifying the output from the amplitude modulation component detection circuit 10, which is composed of an operational amplifier OP and a resistor, and reference numeral 12 designates this amplifier circuit 11, the signal meter circuit 8, and the tuning meter circuit 9.
This is a display unit that is connected to and driven by.

The details are as shown in FIG. 2, and the first display 13 is operated by the signals from the signal meter circuit 8 and the amplifier circuit 11, and the signal is displayed by the tuning meter circuit 9. The first display 13 has its emitter terminal grounded via a resistor _R1 , and its base terminal is connected to the signal meter circuit 8.
and a transistor Q ₁ connected to the amplifier circuit 11,
Q ₂ , a light emitting diode (for example green) OD ₁ and a light emitting diode (for example red) OD ₂ inserted between the collector terminals of these transistors Q ₁ and Q ₂ and the +B power supply.

The second indicator 14 is a transistor whose base terminal is connected to the tuning meter circuit 9, whose collector terminal is connected to the +B power supply, and whose emitter terminal is connected to ground via a resistor _R2 .
Q ₃ and a light emitting diode OD ₃ inserted between the collector terminal of this transistor Q ₃ and the above +B power supply.
, the base terminal is connected between the collector terminal of the transistor Q ₃ and the light emitting diode OD ₃ , the collector terminal is connected to the +B power supply, and the emitter terminal is connected to the ground via the resistor R ₂ similarly to the transistor Q ₃ . It consists of a transistor Q ₄ connected to , and a light emitting diode OD ₄ inserted between the collector terminal of this transistor Q ₄ and the +B power supply.

Note that the light emitting diode of the second display 14
OD ₃ and OD ₄ are the light emitting diodes of the first indicator above.
As long as OD ₁ and OD ₂ are different colors, they may be the same color or may emit light of different colors.

The circuit configuration of the display section 12 is as described above, and each of the light emitting diodes OD ₁ to
OD ₄ is a translucent display panel 1 as shown in Figure 3.
It is located on the back side of 5.

That is, this display panel 15 has a rhombic shape as a whole as shown in the figure, and has a first display surface 15a in the center corresponding to the light emitting diodes OD ₁ and OD ₂ of the first display 13; This first display surface 1
5a is divided into triangular second and third display surfaces 15b and 15c corresponding to the light emitting diodes OD ₃ and OD ₄ of the second display 14, respectively. , 15c so that no light leaks between them.

<Operation of the present invention> The present invention is constructed as described above.
Next, its effect will be explained.

Tuning operation can be performed by operating a tuning knob (not shown) and performing a frequency sweep using the front end 2. However, if a multipath is received during such a frequency sweep, the amplitude modulation component of this multipath will be transmitted to the intermediate frequency amplifier. 4 to the amplitude modulation component detection circuit 10, which is rectified by the diodes D ₁ and D ₂ of the circuit 10 to become a DC component, which is further amplified by the amplifier circuit 11 and transmitted to the transistor of the first display 13 in the display section 12. Raise the base potential of Q ₂ and turn on the transistor Q ₂ .

Therefore, when the transistor Q ₂ is turned on, the light emitting diode OD ₂ lights up, and the first light emitting diode OD 2 of the display panel 15
The display surface 15a of is illuminated with red light emitted by the light emitting diode _OD2 .

The user adjusts the position of the antenna 1 while looking at the light emitting state of the display surface 15a, and adjusts the position of the light emitting diode.
The antenna 1 is positioned where the OD ₂ is turned off, that is, where it is not affected by multipath.

As described above, as the frequency sweep progresses and approaches the frequency of a certain broadcasting station, when it comes to the lower side of that broadcasting station, that is, when the frequency sweep approaches the frequency of a certain broadcasting station, it is When the detected DC output is output, the transistor of the second display 14
As Q ₃ turns off, transistor Q ₄ turns on, and as a result, light emitting diode OD ₄ lights up and the third display surface 15c of display panel 15 becomes a light emitting diode.
Glows with colors emitted by OD ₄ . Therefore, the user can know that the broadcast station is located above the current tuning position.

Also, when the frequency sweep reaches the upper side of the broadcasting station,
That is, when a positive detected DC output is output from the FM detection circuit 5 via the tuning meter circuit 9, the light emitting diode OD ₃ lights up as the transistor Q ₃ of the second display 14 turns on. result,
The second display surface 15b of the display panel 15 lights up with the color emitted by the light emitting diode _OD3 . Therefore, in this case, the user can know that the broadcast station is located below the current tuning position.

This second display 14 shows that when there is no broadcasting station or at the optimum tuning point, the detected DC output of the FM detection circuit 5 is at 0 potential, so both light emitting diodes OD ₃ and OD ₄ do not light up, but when the signal is lower than the optimum tuning point. It lights up when it shifts up or down, helping you easily find the optimal tuning point.

Then, when tuned to the broadcasting station, an intermediate frequency signal is obtained from the intermediate frequency amplifier 4, so the signal meter circuit 8 rectifies it and displays it on the display section 12.
The base potential of the transistor Q ₁ of the first display device 13 is increased to turn on the transistor Q ₁ .

Therefore, the light emitting diode OD ₁ lights up in green, and the green light is emitted from the first display surface 15 a of the display panel 15 .

The user sees this green light on the first display surface 15a and determines that it is the optimum tuning point. Also, at this time, since the DC detection output of the FM detection circuit 5 is at 0 potential, both light emitting diodes OD ₃ ,
Both OD ₄ do not light up.

Then, when the light emitting diode OD ₁ is lit at such an optimal tuning point, when a multipath enters and an amplitude modulation component is input from the intermediate frequency amplification circuit 4 to the amplitude modulation component detection circuit 10, the corresponding amplitude modulation component is inputted to the amplitude modulation component detection circuit 10. circuit 1
0 is rectified as described above and supplied to the base terminal of the transistor _Q2 of the first display 13 via the amplifier circuit 11, turning on the transistor _Q2 and lighting the light emitting diode _OD2 .

Therefore, the display surface 15 of the display panel 15, which was emitting the green light, now lights up with a mixed color of red and green from the light emitting diode _OD2 .
The user can know that multipath is being received and can perform positioning of the antenna 1.

<Effects of the present invention> The present invention is constructed as described above,
The first light emitting element and the second light emitting element are arranged so that a state in which each light emitting element is lit alone and a state in which both are lit at the same time can be distinguished, and the third and fourth light emitting elements are disposed in the first light emitting element. The display panel is provided on both sides of the part where the second light emitting element is provided, and the display panel is provided on the back side of the above light emitting elements in common, so noise such as multipath is prevented during synchronization and non-synchronization. Not only can the tuning point and the detuning above or below the tuning point be displayed on one display panel, but the visibility is much better than when each is displayed individually.

Furthermore, the present invention adjusts the position of the antenna to the optimal reception state by turning on and off the second light emitting element in one display panel, regardless of whether it is tuned or not, and also adjusts the position of the antenna to the optimal reception state by turning on or off the second light emitting element in one display panel. Adjustment to the optimum tuning point can be easily performed by turning on and off the light emitting element and turning on the first light emitting element.

That is, the first part of the display panel is adjusted to the optimum tuning point.
Even if noise such as multipath comes in while the light emitting element is lit, the second light emitting element disposed together with the first light emitting element will light up, so the user will not be affected by the noise. It is possible to immediately know that the antenna is present, and to adjust the antenna position without wasting any time.

Therefore, the user can perform the above-mentioned series of operations from the time of tuning until reaching the tuning point while checking on a single display panel, making it extremely easy to align the antenna and tune the frequency. It can be done easily and accurately.

[Brief explanation of the drawing]

FIG. 1 is a block electrical circuit diagram of an FM radio receiver equipped with an embodiment of the reception status display device according to the present invention, and FIG. 2 is a specific electrical circuit diagram of the display unit in the same electrical circuit diagram. FIG. 3 is a diagram showing a display panel of a display section in the display device section. 1: Antenna, 4: Intermediate frequency amplifier, OD ₂ : Light emitting diode.

Claims (1)

[Claims for Utility Model Registration] A first light emitting element that lights up based on an intermediate frequency signal obtained from an intermediate frequency amplifier at a tuning point; a second light emitting element that lights up based on the generated noise component obtained through the intermediate frequency amplifier, and a third light emitting element that lights up based on it when the output of the detection stage deviates below or above the tuning point. a fourth light-emitting element; the first light-emitting element and the second light-emitting element are arranged so as to distinguish between a state in which each light-emitting element is lit alone and a state in which both are lighted at the same time; a radio receiver comprising a display panel in which a fourth light emitting element is provided on both sides of a portion where the first light emitting element and the second light emitting element are provided, and a display panel in which each of the light emitting elements is commonly disposed on the back side; Receiving status display device for the machine.