JPH0548505A - On-vehicle diversity receiver - Google Patents

Abstract

PURPOSE:To obtain a best pattern without ghost in the television receiver mounted on a mobile body. CONSTITUTION:A sub RF switch 3b is controlled so as to select sequentially each radio wave received by other antennas than an antenna received a radio wave selected by a main RF switch 3a among plural diversity antennas 1a,..., 1d. An electric field strength and a video signal detected by a sub tuner unit 4b and a sub video detection circuit 5b from the radio wave selected sequentially via the sub RF switch 3b are compared respectively with the electric field strength and a video signal detected by a main tuner unit 4a and a main video detection circuit 5a and the main RF switch 3a is controlled to select the diversity antennas 1a,..., 1d based on the result of comparison.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle-mounted diversity receiving device having a plurality of diversity antennas so that the best image can be received in a mobile body such as a vehicle-mounted television receiver.

[0002]

2. Description of the Related Art In a television receiver in a moving body such as a vehicle, a received image is severely disturbed due to fading. Therefore, a diversity receiving system using a plurality of antennas is used to reduce such a disturbed received image. Has been adopted.

The diversity receiving system uses 2 to 4 antennas whose directivity and mounting position are changed, and the influence of fading is reduced because the time change of the electric field strength received by each antenna while traveling is independent. It is possible.

More specifically, the diversity reception system compares the video signal levels received by the antennas while sequentially switching the above-mentioned 2 to 4 antennas by 1H, for example, and compares the radio wave with the highest electric field strength. It is designed to select the received antenna. Further, this comparison is performed once every 1 to several V during the B blanking period.

[0005]

In the conventional vehicle-mounted diversity receiver, only the electric field strength is targeted,
Since the effects of ghosts are not taken into consideration, an antenna with a lot of ghosts is selected, or an antenna with a phase difference with the received image from the currently selected antenna is selected, resulting in screen sway or flicker. There is a problem that the change in screen brightness cannot be suppressed.

Further, if the frequency of switching the antennas is increased, there is a problem that the screen may become rather difficult to see, and there is a method of using a large number of antennas having a sharp directivity in order to solve such a problem. There is a problem that it is not possible to execute because there is no space to install it.

The present invention has been made in view of the above,
An object of the invention is to provide a vehicle-mounted diversity receiving device that can obtain the best screen without ghost.

[0008]

In order to achieve the above object, a vehicle-mounted diversity receiving apparatus according to the present invention includes a diversity antenna group including a plurality of antennas and a radio wave received by one antenna of the diversity antenna group. The main switch means for selecting, the main diversity tuner means for detecting the electric field strength of the received radio wave and the video signal from the radio wave selected via the main switch means, and the antenna of one of the diversity antenna groups. Sub-switch means for selecting radio waves, sub-diversity tuner means for detecting the electric field strength of received radio waves and video signals from the radio waves selected via the sub-switch means, and an antenna for receiving the radio waves selected by the main switch means. Select each radio wave received by an antenna other than The switching means is controlled, and the electric field strength and the video signal detected by the sub-diversity tuner means from the radio waves sequentially selected through the sub-switch means are compared with the electric field strength and the video signal detected by the main diversity tuner means, respectively. Comparison means,
The gist of the present invention is to have a control means for controlling the main switch means so as to switch the antenna based on the comparison result of the comparison means.

[0009]

In the vehicle-mounted diversity receiver of the present invention,
Among the diversity antenna group consisting of a plurality of antennas, the sub-switch means is controlled so as to sequentially select each radio wave received by the antenna other than the antenna receiving the radio wave selected by the main switch means, and via this sub-switch means The electric field strength and the video signal detected by the sub-diversity tuner means from the sequentially selected radio waves are respectively compared with the electric field strength and the video signal detected by the main diversity tuner means, and the main switch means is used to switch the antenna based on the comparison result. Are in control.

[0010]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of a vehicle-mounted tie diversity receiving apparatus according to an embodiment of the present invention. The vehicle-mounted diversity receiving device shown in the figure has four diversity antennas 1a, ..., 1d, and the radio waves received by the diversity antennas 1a, ..., 1d are transmitted to the main RF via distributors 2a, ..., 2d. It is supplied to the switch 3a and the sub RF switch 3b. The main RF switch 3a and the sub RF switch 3b are respectively received by the diversity antennas 1a to 1d, and the distributor 2
Any one of the received radio waves supplied via a, ~, 2d
One of them is supplied to the main tuner unit 4a and the sub-tuner unit 4b.

The main tuner unit 4a and the sub-tuner unit 4b select desired signals from the received radio waves supplied via the main RF switch 3a and the sub-RF switch 3b, and the main video detection circuit (PIF) 5 respectively.
a, audio detection circuit (SIF) 6 and sub-picture detection circuit (PIF) 5b. The main video detection circuit 5a and the audio detection circuit 6 respectively detect a video signal and an audio signal from the signal supplied from the main tuner unit 4a, and output these video signal and audio signal. Further, the sub video detection circuit 5b detects a video signal from the signal supplied from the main tuner unit 4a.

The video signals respectively detected by the main video detection circuit 5a and the sub video detection circuit 5b are supplied to the main sync separation circuit 7a and the sub sync separation circuit 7b, respectively, and the sync signals are separated, and the sync signals are separated. The signal is supplied to the control circuit 9 including, for example, a microcomputer. The control circuit 9 is supplied with a vehicle speed detection signal from a vehicle speed detection device (not shown) that detects the traveling speed of the vehicle.

Further, the respective video signals detected by the main video detection circuit 5a and the sub video detection circuit 5b are supplied to a comparator 8, and in the comparator 8, the video signal level between the respective video signals will be described later. And the phase difference is compared,
Thereby, the correlation between both video signals is calculated and supplied to the control circuit 9.

The control circuit 9 controls the sync signals from the main sync separation circuit 7a and the sub sync separation circuit 7b, the video detection signals from the main video detection circuit 5a and the sub video detection circuit 5b,
The output signal from the comparator 8 is supplied to control the main RF switch 3a and the sub RF switch 3b,
I try to receive the radio wave from the best antenna.

The main RF switch 3a, the main tuner unit 4a, the main video detection circuit 5a, the audio detection circuit 6 and the main synchronization separation circuit 7a constitute the main tuner which is the main diversity tuner means of the present invention, and the sub tuner. RF
The switch 3b, the sub tuner unit 4b, the sub video detection circuit 5b, and the sub sync separation circuit 7b constitute a sub tuner which is a sub diversity tuner unit of the present invention.

The control circuit 9 has a diversity antenna selected by the main RF switch 3a of the main tuner, for example, the diversity antenna 1a.
If you select, this diversity antenna 1a
On the other hand, other diversity antennas, that is, the diversity antennas 1b, 1c, 1d are controlled to be sequentially selected via the sub RF switch 3b of the sub tuner, and the electric field strength of the detection signal received via the diversity antenna 1a, The video signal level and phase difference are sequentially compared with the electric field strength, video signal level and phase difference of each detection signal received via each diversity antenna 1b, 1c, 1d, and the best antenna is detected by this. The main RF switch 3a is controlled so that the detected radio wave of the antenna is drawn into the main tuner.

The detailed circuit structure of the comparator 8 is shown in FIG. 2. The comparator 21 compares the video signal of the main tuner with the reference voltage Vra, and the video signal of the sub tuner is referenced by the comparator 23. The voltage Vra is compared with the reference voltage Vra.
The larger video signal part is extracted as a binary signal,
The extracted video signal parts are supplied to the exclusive OR gate 25, the signals of different parts of both signal parts are extracted, and the signals of the different parts are supplied to the counter 27,
The signal magnitudes of these different parts are counted. That is, the counter 27 outputs the signal magnitudes of different portions of the video signal from the main tuner and the video signal from the sub tuner. Further, the comparator 8 shown in FIG.
The video signal of the main tuner is compared in the comparator 31 with the reference voltage Vrb, and the video signal of the sub-tuner is compared in the comparator 33 with the reference voltage Vrb. Each sync signal is supplied to the exclusive OR gate 35, different parts of both sync signals are taken out, the different parts of this sync signal are supplied to the counter 37, and the sizes of the different parts of this sync signal are counted. There is. That is,
This counter 37 outputs the magnitudes of different parts of the sync signal of the video signal output from the main tuner and the sync signal of the video signal output from the sub tuner. That is, it indicates the phase difference between the two signals. In other words, counter 2
The smallest value of 7, 37 is the received image most similar to the received image currently received by the main tuner.

FIG. 3 is a block diagram showing another circuit configuration of the comparator 8. The comparator 8 shown in the figure includes an A / D converter 41, 43 and a digital comparator 45.
A / D converters 41 and 4 are used.
Video signals from the main tuner and the sub-tuner are respectively supplied to 3, and these video signals are converted into digital signals and compared by the digital comparator 45. The digital comparator 45 compares both input signals, outputs a portion where the two signals do not match as a signal, and supplies the signal to the counter 47 and the counter 49.
The counter 47 counts different parts of the video signal in order to count the clock signal gated by a signal obtained by inverting the gate signal corresponding to the H blank period, and the counter 49 counts the clock signal gated in the gate signal. For counting different parts of the sync signal.

Next, the operation will be described with reference to the flow chart shown in FIG. 4 and the timing chart shown in FIG.

First, the control circuit 9 controls the main RF switch 3a to select one of the diversity antennas 1a to 1d for the main tuner (step S).
1). This is selected during vertical blanking (V blanking) as shown in FIG. 5 (a), and for example, as shown in FIG. 5 (d), the first diversity antenna 1 a.
Is selected.

Next, the control circuit 9 performs an operation of reading the detection level of the video signal in order to detect the electric field strength of the radio wave received by each of the diversity antennas 1a, 1a, 1d. 3b for controlling the diversity antenna 1a for the sub tuner,
, 1d are selected and switched (step S3), and the detection level of the video signal from the sub-tuner received through the selected diversity antenna is read and stored (step S7). The above process is shown in FIG.
And in (f), one by one is repeated for all four diversity antennas as shown sequentially at short intervals between V blanking signals, and it is checked that the electric field strength is read from each diversity antenna (step S7), and then proceeds to step S9.

In the next step S9 and subsequent steps, the operation of reading the output signal of the comparator 8 in order to detect the video signal level and the phase difference from the video signal received and detected through each of the diversity antennas 1a to 1d is performed. For this purpose, first, the sub RF switch 3b is controlled, and step S
Except for the diversity antenna 1a selected for the main tuner shown by 1, the tie diversity antennas 1b to 1d for the sub tuner are selected and switched (step S9). Then, the video signal from the sub-tuner received via the selected diversity antenna is compared with the video signal from the main tuner received via the diversity antenna 1a for the main tuner selected in step S1 in the comparator 8. The output result is read and stored (step S11). The above process is performed one for each of the remaining three diversity antennas, as shown by the spacing between the V blanking signals in FIGS. 5 (d) and 5 (e), ie diversity antennas 1b, 1c. , 1d are sequentially repeated for all three diversity antennas, and a comparator 8 for each diversity antenna is provided.
When it is checked that the output signal of is read (step S13), the process proceeds to step S15.

In step S15, the detection levels sequentially read through the diversity antennas 1a, 1a, and 1d selected for the sub-tuner in step S5 are compared with each other, and the antenna having the highest electric field strength is selected from the detection levels. In addition, each output signal of the comparator 8 with respect to the video signal sequentially read through each diversity antenna selected for the sub tuner in step S11, that is, the video signal level and the phase difference received by the main tuner and the sub tuner, respectively. The respective output signals of the comparison result of (1) are compared based on the correlation, and the optimum antenna is selected from these comparisons. Then, the main RF switch 3a is switched so that the received radio wave from the selected optimum antenna is selected and supplied to the main tuner (step S17). As a result, for example, if another diversity antenna, for example, the diversity antenna 1c is selected for the diversity antenna 1a selected in step S1, then the above-described steps S3 to S17 are repeated for this diversity antenna 1c. As a result, the optimum diversity antenna is always selected from the correlation between the electric field strength and the received video signal, that is, the video signal level and the phase difference. More specifically, first, the one having the strongest electric field strength is selected, and the one having the largest correlation, for example, 70% or more, between the detected video signals with respect to the change in the video signal level and the phase difference is selected among the strongest electric field strengths. I am trying.

In the above embodiment, not only the conventional comparison of the electric field strengths but also the comparison of the received video signals are performed. In the comparison of the received video signals, the difference between the video signal levels and the reception by the main tuner are mainly performed. The video signal and the phase difference with the video signal received via each diversity antenna selected by the sub tuner are taken as items, and the main tuner receives them by selecting the antenna whose difference is the minimum or within a certain fixed value. The change in screen position and the change in screen brightness between the current field and the next field are minimized.

Further, the comparison of the electric field strengths is carried out by using the detection level. Since the antenna having the lowest signal level is the antenna having the highest electric field strength, it is switched to the sub tuner for comparison with the receiving antenna in the main tuner. If there is no stronger antenna than the electric field strength of the receiving antenna of the main tuner, it is not necessary to switch, but if there is a stronger one, compare it with the video signal currently being received by the main tuner, and Among the antennas having a stronger electric field strength than the antenna selected for the tuner, the antenna that can obtain an image with the smallest screen position change and screen brightness change is selectively switched for the main tuner.

However, the images selected by the antennas selected by comparing the electric field strengths have a certain value or more, for example, about 30.
% Or more If the main tuner is different from the image currently being received, the antenna is not switched. This is because a change in the horizontal position of the screen and a change in the screen brightness due to the switching of the antenna are completely discontinuous movements, and thus the screen becomes very difficult to see. for that reason,
In the conventional diversity receiving method, if the electric field strengths are not separated by a certain value or more, for example, about 3 to 6 dB or more so that the antennas are not frequently switched, the antennas are switched even if there is a better one than the currently receiving antenna. I'm trying not to.

In this embodiment, such processing can be performed by comparing received video signals.
Accurate judgment is possible. That is, even if the antenna has an electric field strength of 3 dB or less, if a video signal pattern having a strong correlation with the antenna currently being received by the main tuner is obtained, the switching is actively performed, and conversely, the electric field strength is improved. Even if it is 6 dB or more, if the correlation is about 70% or less, the antennas are not switched. However, when the electric field strength of the currently implemented antenna is a weak electric field of 30 dB or less, it is better to switch to an antenna having a stronger electric field strength, so that the above processing is not performed.

Next, a method of determining the optimum antenna from the detection output level obtained as described above and the output of the comparator 8 will be described. The detection output level is converted into an 8-bit digital signal and taken into the control circuit 9, and the output from the comparator 8 is 16 bits for both video and synchronization.

First, the correlation C between the video signal pattern received and detected by the main tuner and the video pattern received and detected by the sub tuner is calculated by the following equation.

C = (P1 + P2 * 4.5) / 2 where P1 is the video output signal of the comparator 8, and P1
Reference numeral 2 is an output signal for synchronization of the comparator 8, and the coefficient 4.5 multiplied by P2 is a ratio of the video period and the blanking period in one horizontal period, and both the position of the sync signal and the video signal pattern are shown. It is used to evaluate with the same weighting.

Next, the detection output level is multiplied by 256 to obtain 16
Letting D be a bit, the final antenna evaluation coefficient E is calculated by E = C + D. In this example,
The amount of change in D when the electric field strength changes by about 6 dB and C when the received video signal pattern obtained by C changes by about 30%
Since it is considered that the change amounts of 1 are equal, E can be used as the evaluation coefficient.

As described in steps S3 and S5 of FIG. 4, each diversity antenna 1a,
The detection output level (electric field strength) from ~, 1d is taken in, and the electric field strength is stronger than the current antenna used in the main tuner, and C is less than 30% of the maximum value. If there is an antenna other than the current antenna, the evaluation factors E are compared, the smallest of these is selected as the optimum antenna, and the current antenna used in the main tuner is used instead. Switch and use.

The comparison of the electric field strengths is made by comparing (e) and (f) of FIG.
As shown in, it is performed during the V blanking period.
Since comparison of video signals requires a certain period, one field period during the V blanking period is divided as shown in (g) of FIG.

FIG. 6 shows a state in which four diversity antennas 1a, 1a, and 1d are compared during one field. On the left side of the figure, the field currently received by the main tuner is shown. On the right side are three comparisons A ₀ , B ₀ , C ₀ with the antenna pulled in by the subtuner.
As a result of this comparison, as described above, the optimum antenna is switched to the main tuner and used in the next reception field of the main tuner.

The comparison shown in FIG. 6, that is, three comparisons in one field is performed when the traveling speed of the vehicle is as high as 30 km / h or more,
When the traveling speed is high as described above, the radio wave state changes in units of one field, so that the comparison is made within one field.

The traveling speed of the vehicle is, for example, 30 km / h.
When it is lower than the following, one comparison is performed for one field and three comparisons are performed for three fields as shown in FIG.

[0038]

As described above, according to the present invention,
Among the diversity antenna group consisting of a plurality of antennas, the sub-switch means is controlled so as to sequentially select each radio wave received by the antenna other than the antenna receiving the radio wave selected by the main switch means, and via this sub-switch means The electric field strength and the video signal detected by the sub-diversity tuner means from the sequentially selected radio waves are respectively compared with the electric field strength and the video signal detected by the main diversity tuner means, and the main switch means is used to switch the antenna based on the comparison result. Is controlled, it is possible to obtain a good screen by suppressing the screen lateral vibration and the screen brightness change.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a vehicle-mounted diversity receiver according to an embodiment of the present invention.

2 is a block diagram showing a detailed configuration of a comparator used in the vehicle-mounted diversity receiver of FIG.

3 is a block diagram showing another detailed configuration of a comparator used in the vehicle-mounted diversity receiver of FIG. 1. FIG.

FIG. 4 is a flowchart showing an operation of the vehicle-mounted diversity receiver of FIG.

5 is a timing chart showing the operation of the vehicle-mounted diversity receiver of FIG.

FIG. 6 is an explanatory diagram showing a comparison operation in the vehicle-mounted diversity receiver of FIG.

FIG. 7 is an explanatory diagram showing a comparison operation in the vehicle-mounted diversity receiver of FIG.

[Explanation of symbols]

 1a, ~, 1d Diversity antenna 3a Main RF switch 3b Sub RF switch 4a Main tuner unit 4b Sub tuner unit 5a Main video detection circuit 5b Sub video detection circuit 7a Main sync separation circuit 7b Sub sync separation circuit 8 Comparator 9 Control circuit

Claims (2)

[Claims] 1. A diversity antenna group composed of a plurality of antennas, a main switch means for selecting a radio wave received by one antenna of the diversity antenna group, and a radio wave selected via the main switch means. Main diversity tuner means for detecting the electric field strength of a radio wave and a video signal, a sub switch means for selecting a radio wave received by one antenna of the diversity antenna group, and a radio wave selected via the sub switch means The sub-tiency tuner means for detecting the electric field strength of the radio wave and the video signal, and the sub-switch means for sequentially selecting each radio wave received by an antenna other than the antenna receiving the radio wave selected by the main switch means. , The sub switches from the radio waves sequentially selected through the sub switch means. Comparing means for respectively comparing the electric field strength and the video signal detected by the diversity tuner means with the electric field strength and the video signal detected by the main diversity tuner means, and the antenna for switching the antenna based on the comparison result in the comparing means. An in-vehicle diversity receiving device, comprising: a control unit that controls a main switch unit. 2. A speed detecting means for detecting a running speed of a vehicle, and when the running speed of the vehicle detected by the speed detecting means is equal to or higher than a predetermined speed, the comparison means performs the comparison within one field to obtain the predetermined speed. The vehicle-mounted diversity receiving apparatus according to claim 1, further comprising a comparison control unit that controls the comparison to be performed over a plurality of fields when the number is less than 1.