JPH0526824Y2 - - Google Patents

Description

[Detailed description of the invention] [Industrial application field] This invention relates to receivers, and in particular, the state of the input signal near the reception frequency of the receiver can be set to a reception mode in which the reception frequency and the center frequency do not match. The present invention relates to a receiver equipped with a spectrum display device capable of displaying a spectrum.

[Conventional technology and its issues]

In recent years, in order to check the state of radio waves near the receiving frequency of the receiver, a spectrum display device such as a band scope or a spectrum analyzer has been installed in the receiver.

The above-mentioned spectrum display device can display the state of radio waves in a specific band as a spectrum, and by being installed in a receiver, the state of the input signal near the receiving frequency of the receiver can be displayed on the display screen of the display means. The advantage is that quick and accurate tuning operations can be performed using not only auditory senses but also visual senses, such as tuning the received frequency by aligning the peak position of the spectrum with a predetermined position on the display screen. There is.

FIG. 2 is a block diagram showing the basic configuration of a bandscope (spectrum analyzer).

The sawtooth sweep signal oscillated from the sweep signal oscillation means 1 is input to the local oscillation means 3, where it is input to the mixer 41 as a local oscillation signal that changes according to the voltage change of the sawtooth sweep signal. A signal to be displayed as a spectrum, such as a receiver input signal, is input to this mixer 41, and a signal having a frequency that is the sum or difference between the frequency of this input signal and the frequency of the local oscillation signal is obtained. The output of this mixer 41 is input to a filter 43 via an amplifier 42, where an intermediate frequency signal having a constant frequency defined by the filter 43 is obtained. This intermediate frequency signal is input to the vertical axis of the display screen of the display means 45 via the detector 44 and the like.

On the other hand, the sweep signal is inputted onto the horizontal axis of the display screen of the display means 45, thereby making it possible to display a spectrum on the display screen, with the horizontal axis representing the frequency and the vertical axis representing the intensity of the input signal. can.

By the way, when the spectrum display device is installed in a receiver, the spectrum display device is usually connected to a relatively wide-band intermediate frequency amplification stage, and the receiver's intermediate frequency signal centered at the receiving frequency is input. has been done. As a result, the intensity of the reception frequency of the receiver is always displayed at the center position on the display screen.

When the reception mode of the receiver is set to AM or FM, the peak position of the frequency spectrum appearing on the display screen is displayed at the center position in the horizontal direction on the display screen of the display 45. By doing so, the receiving frequency can be tuned.

However, in SSB (USB, LSB) used for amateur radio communications, the frequency of the carrier wave is referred to as the frequency of the signal, rather than the frequency corresponding to the peak of the signal's spectrum. Therefore, for example, the peak of the spectrum of a 14.1 MHz USB signal appears at a frequency around 14.1015 MHz, which is about 1 to 2 kHz higher than 14.1 MHz. Therefore,
Frequency _a where the peak appears as shown in Figure 3a
If it is placed at the center position l in the horizontal direction on the display screen of the display means 45, the receiving frequency of the receiver will be set to the above frequency _a , and it will be possible to accurately receive the target frequency ₀ . It turns out you can't do it. In order to properly receive the target signal, tune to a frequency that is about 1 to 2 KHz lower than the frequency at which the peak of the spectrum of the target signal appears. A tuning operation is required to match the frequency ₀ ) to the center position l in the horizontal direction on the display screen, which negates the benefits that would originally arise from installing the spectrum display device.

This idea was proposed in view of the above-mentioned conventional circumstances, and regardless of the mode in which the receiving frequency and center frequency do not match, the peak of the spectrum of the input signal appearing on the display screen and the receiving frequency of the receiver It is an object of the present invention to provide a receiver equipped with a spectrum display device that displays the spectrum in a consistent state and facilitates tuning operations.

[Technical background of this invention]

Therefore, the display has been designed so that a unified tuning operation (adjusting the peak position of the displayed spectrum to the center position of the display screen) can be performed in any reception mode: AM, FM, or SSB. In order to change or adjust the center frequency of the spectrum displayed on the screen according to the reception mode, local oscillation means 3 is explained as below.
The bias voltage is adjusted.

That is, FIG. 4a is an equivalent circuit diagram showing the connection state of the sweep signal oscillation means and the local oscillation means, and FIG. 4b is an equivalent circuit diagram showing the maximum value V _Max and minimum value of the sweep signal.
This shows the relationship between V _Mio and center voltage V ₀ . The resistance value of the bias setting means 7 of the local oscillation means 3 is
R _B , its bias voltage (voltage across the bias resistor) is V _B , and the instantaneous voltage of the sweep signal oscillator output is V, then the voltage V A at point A, which is the input terminal of the bias voltage of the local oscillation means ₃ , is as follows. become that way.

V _A = (V - V _B ) x R _B / R _B + R _S + V _B V _AMax = (V _Max - V _B ) x R _B / R _B + R _S + V _B V _AMio = (V _Mio - V _B ) × R _B /R _B +R _S +V _BBy the way, the voltage at point A that determines the left and right center positions on the display screen, the center voltage V _A0 of V _A , is V _A0 = V _AMax + V _AMio /2 = {(V _Max + V _Mio −2V _B ) (R _B /R _B +R _S )+2V _B }/2 Here, since V _Max +V _Mio /2=V ₀ , V ₀ : Center voltage of the sweep signal (voltage V) ∴V _A0 = (V ₀ - V _B ) (R _B /R _B + R _S ) + V _B ...(1) It is expressed by the formula (1).

In this circuit, the sweep signal generating means 1
A span adjustment means 2 having a variable resistance set to a resistance value R _S is disposed at a subsequent stage to expand or contract the span (band) of the frequency to be swept.

Therefore, from equation (1), the voltage V _A0 that determines the center position l on the display screen depends on the bias setting means 7 when the resistance R _S value of the span adjustment means 2 is constant, and the receiving frequency By making it possible to arbitrarily adjust only the bias setting means regardless of the bias setting means, it is possible to shift only the spectrum displayed on the display screen to a desired position in the horizontal direction.

Therefore, even in a mode where the peak position of the spectrum and the receiving frequency do not match (a mode where the receiving frequency and the center frequency do not match), the receiving frequency of the receiver does not change at all, and only the displayed spectrum is changed in the left and right directions. This allows the actual received frequency ₀ to match the peak frequency _a of the displayed spectrum at the center.

[Means to solve the problem]

Based on the above-mentioned technical background, in order to achieve the above object, this invention inputs a sawtooth sweep signal oscillated from a sweep signal generating means to a local oscillation means, and from the local oscillation means, the sawtooth waveform Obtain a local oscillation signal with a frequency that changes in response to the voltage of the sweep signal, input it to a mixer, calculate the difference or sum of the frequency of the received signal and the frequency of the local oscillation signal, and pass it through a filter. By obtaining an intermediate frequency signal of a predetermined frequency, inputting the intermediate frequency signal to the vertical axis of the display screen of the display means, and inputting the above-mentioned sweep signal to the horizontal axis of the display means, the frequency corresponding to the input signal can be determined. A spectrum display device for an input signal, wherein a spectrum is displayed on a display screen with the horizontal axis as frequency and the vertical axis as intensity, and the bias voltage of the local oscillation means determines the center position of the frequency displayed on the display screen. The following measures are adopted assuming that the receiver is equipped with:

That is, the bias voltage is adjusted according to the reception mode set by the mode setting means of the receiver, and the center position on the display screen of the display means corresponding to the center of gravity frequency and the spectrum of the signal corresponding to the reception frequency are adjusted. Bias setting means for shifting the spectrum on the display screen so that the peak position of the oscillation means coincides with the peak position of the local oscillation means is provided in the preceding stage of the local oscillation means.

[Effect]

With this configuration, in the present invention, even in a mode where the receiving frequency and the center frequency do not match, the peak of the spectrum corresponding to the target frequency is always displayed at the receiving frequency position (the center position of the display). The display spectrum can be shifted so that the

〔Example〕

Figure 1 is a circuit diagram showing the configuration of this invention.
FIG. 2 is a block circuit diagram showing an example of a spectrum display device to which this invention is applied.

Its basic configuration is shown in FIG. 2, in which a sweep signal obtained from the sweep signal oscillation means 1 controls the display means 45, and the sweep signal
The signal is input to the local oscillation means 3, where it is converted into a local oscillation signal that sweeps a predetermined frequency band, and is input to the mixer 41. A signal near the intermediate frequency of the receiver 6 is also input to this mixer 41,
It is mixed with the local oscillation signal and converted into a signal _V having a frequency corresponding to the filter 43. This signal _v
is amplifier 42, filter 43, daytector 4
4, etc., to a display 45, and the input signal near the receiving frequency is displayed as a spectrum on this display.

In such a spectrum display device, the span of the frequency band displayed on the display 45 is determined by the amplitude of the sweep signal, and the center frequency is determined by the center voltage of the sweep signal. Further, this center frequency and the reception frequency of the receiver 6 are made to match.

In this configuration, the spectrum of the input signal in modes such as AM and FM will match the displayed frequency and the frequency of the peak of the spectrum, so it is possible to tune the receiving frequency to a specific signal. In this case, the tuning operation should be performed so that the peak of the spectrum corresponding to the signal is located at the center of the display.

However, SSB (USB, LSB) signals are
There is a difference of 1 to 2 KHz between the reception frequency called in the amateur radio field and the peak frequency of the corresponding signal spectrum. If the frequency _a where the peak appears is placed at the receiving frequency position l as shown in
This means that the desired frequency ₀ cannot be received accurately.

Therefore, in this invention, in addition to the above configuration, a bias setting means 7 is provided which can change the bias for determining the oscillation frequency of the local oscillation means in accordance with the mode. It is linked to the mode setting means 6, and applies a required bias voltage to the local oscillation means 3 in accordance with the mode designated by the mode setting means 6.

According to this configuration, the left and right center positions on the screen are determined by the formula (1): V _A0 = (V ₀ - V _B ) (R _B /R _B + R _S ) + V _B ...(1) The center voltage V _A0 of the voltage V _A at point A can take an appropriate value depending on the reception mode.

This bias setting means 7 consists of a switching resistor, for example, as shown in the figure, and for example, in the case of USB,
The bias voltage is set to be lower than that for AM.

With this configuration, as in the case of AM and FM, it is possible to precisely tune to frequency ₀ by performing a tuning operation so that the peak position of the spectrum of the target signal is at the center of the display.

The above description assumes that the bias voltage of the local oscillation means 3 and the center voltage of the sweep signal are not changed by the operation of the spectrum display device, but conventional spectrum display devices satisfy this condition. I stopped talking. However, the applicant has disclosed that the bias setting means 5 of the sweep signal oscillation means 1
A spectrum display device in which the bias voltage of the local oscillation means 3 and the center voltage of the sweep signal are made to match, so that the span change by the span change means 2 does not affect the center voltage of the sweep signal or the bias voltage of the local oscillation means 3. As shown in Figure 1, we have developed and have already filed an application. Therefore, this invention will exhibit its original effects when applied to the above-mentioned spectrum display device developed by the applicant.

In the embodiment of the present application, the SSB mode has been described as an example, but it goes without saying that this invention can be applied to other modes where the nominal frequency and the center frequency do not match, such as the RTTY mode.

[Effect of idea]

As explained above, this invention allows a receiver equipped with a spectrum display device to display the peak position of the spectrum in accordance with the specified mode even in a reception mode where the reception frequency and center frequency do not match. can be shifted.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram showing one embodiment of this invention, FIG. 2 is a block diagram showing an outline of a spectrum display device, and FIG. 3 is a conceptual diagram showing the relationship between the displayed spectrum and the center position in the spectrum display device.
FIG. 4 is a circuit diagram and a sweep signal waveform diagram showing the connection state of the sweep signal oscillation means and the local oscillation means. In the figure, 1...sweep signal oscillation means, 3...local oscillation means, 45...display means, 7...bias setting means.

Claims (1)

[Scope of Claim for Utility Model Registration] A sawtooth sweep signal oscillated from the sweep signal generating means is input to local oscillation means, and the local oscillation means generates a frequency that changes in accordance with the voltage of the sawtooth sweep signal. Obtain a local oscillation signal, input it to a mixer, calculate the difference or sum of the frequency of the received signal and the frequency of the local oscillation signal, and obtain an intermediate frequency signal of a predetermined frequency via a filter. By inputting the above-mentioned sweep signal to the vertical axis of the display screen of the display means and inputting it to the horizontal axis of the display means, the frequency spectrum corresponding to the input signal is displayed with the horizontal axis as the frequency and the vertical axis as the intensity. display on the screen,
and in a receiver equipped with an input signal spectrum display device in which the bias voltage of the local oscillation means determines the center position of the frequency displayed on the display screen, the mode setting means of the receiver sets: The bias voltage is adjusted according to the received reception mode, and displayed so that the center position on the display screen of the display means corresponding to the reception frequency matches the peak position of the spectrum of the signal corresponding to the reception frequency. 1. A receiver equipped with a spectrum display device, characterized in that bias setting means for shifting the spectrum on the screen is provided at a stage upstream of local oscillation means.