JP2906639B2 - Teletext receiving system for mobile objects - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a teletext receiving system for a mobile body suitable for being applied to a mobile body such as a train.

[Summary of the Invention]

The present invention, in a teletext receiving system mounted on a moving object such as a train, a diversity antenna is configured and received by a plurality of antennas, and switching of each antenna is performed at intervals of 1 second ± 0.5 seconds, This is a telecommunications broadcasting that can be favorably received by a diversity antenna.

[Conventional technology]

2. Description of the Related Art In recent years, a television receiver is mounted on a moving body such as a train, and a video reproduced from a VTR or the like is received to provide services to passengers. In this case, an antenna is mounted on the roof of a train, and a television broadcast signal from a terrestrial transmitting station is received and received by the antenna.

[Problems to be solved by the invention]

However, such television broadcast signals can be received only when traveling in a place where the radio wave condition is relatively good. In other words, in the case of a moving object traveling in an area with many obstacles such as a building, such as a city center, there are few places where the broadcast signal from the transmitting station can be received well without unnecessary radiation. Reception conditions were very poor when simply attached to the body, and in many cases, the image was in a state that was unfit for practical use. For example, in the case of a train running on the Yamanote line that runs in almost the center of Tokyo, the distance from the transmitting station is very short, and it is a strong electric field area that can receive well with an antenna with a simple structure, but obstacles such as buildings There were so many things that it was almost impossible to receive television broadcasts without ghosts using conventional techniques.

In addition, although radio waves for teletext are transmitted using part of the television broadcast signal, since the teletext signal is converted into digital data and transmitted, the generation of ghosts is extremely disliked, It was not possible to receive teletext on mobiles.

Furthermore, if the direction of the transmitting station as viewed from the mobile is constantly changing, it is not impossible to keep the antenna constantly pointing in the direction of the transmitting station, but complicated tracking devices are required and generally fixed. In many cases, the signal is received by the antenna, which deteriorates the reception state. For example, in the case of a train that runs around the transmitting station in a loop (such as the Yamanote Line in Tokyo), the direction of the transmitting station viewed from the train is one round of travel.
It changed 360 °, and it was impossible to always receive good signals with a fixed antenna.

In order to solve this problem, for example, when receiving a television broadcast from a mobile body such as an automobile, a plurality of antennas are installed, and reception is switched by switching to a reception state having a good reception among the plurality of antennas. A so-called diversity antenna is being constructed. In this case, the receiving state is determined in one field or one frame period of the received video signal, and the antenna is switched to an antenna having a good receiving state even slightly, so that disturbance of the received image is minimized. According to this diversity antenna, the possibility of good reception is higher than that of reception using only one antenna.

However, since the teletext is transmitted as digital data, if the received data is interrupted during reception of the teletext program, a reception error occurs and decoding of the teletext program becomes impossible. Therefore, if the reception of the teletext is performed by the diversity antenna, a reception error occurs every time the antenna is switched, and the reception of the teletext by the diversity antenna in which the reception antenna is frequently switched is not practical.

An object of the present invention is to make it possible to receive a text broadcast satisfactorily on a moving body such as a train.

[Means for solving the problem]

For example, as shown in FIG. 1, the present invention provides a plurality of antennas (30a), (30b), (30c), (3
0d) and the plurality of antennas (30a), (30b), (30
antenna switching means (41) for selecting an antenna having the best reception condition among c) and (30d); and a television broadcast receiving tuner for demodulating a signal from the antenna selected by the antenna switching means (41). (43), a teletext decoder (46) for demodulating a teletext signal from the output of the tuner (43), and display means (101), (102), () for displaying the output of the teletext decoder (46). 103) ‥‥ (1
24), and switching of a plurality of antennas by the antenna switching means (41) is performed at intervals of seconds ± 0.5 seconds.

[Action]

In the teletext, one screen is transmitted in about 0.5 seconds using the vertical blanking period of the television broadcast signal.
Therefore, by performing the switching by the antenna switching means at intervals of 1 second ± 0.5 seconds, the receiving antenna is less likely to be switched while receiving one screen of the teletext, and the diversity antenna is used. Teletext broadcasting can be received well.

〔Example〕

Hereinafter, an embodiment of the present invention will be described with reference to FIGS.

In this example, the present invention is applied to a receiving system for displaying a text broadcast on a television receiver mounted on a train. First, the overall configuration of the receiving system will be described.

1 and 2, (1) shows the body of a train, and six doors (entrances) (11), (12), (13) (13) on the side of the body (1). 16) and (17),
(18), (19) and (22) are provided, and the television receivers (101), (102), and (102) are provided above the left and right door pockets of the doors (11) to (22) in the vehicle. (103) ‥‥ (124) are installed. For example, as shown in FIG. 2, television receivers (117) and (118) are mounted above the left and right door pockets of the door (19). In this case, the respective television receivers (101), (102), (103) ‥‥ (124)
Is a thin type using a liquid crystal panel or the like.

Each of the television receivers (101), (10)
2), (103) and (124) display teletext. Four antennas (30a), (30b), (30c), and (30d) for receiving the teletext are It is mounted around the ventilators (3) and (4) on the roof (2) of the vehicle body (1). In this case, each antenna (30a),
(30b), (30c) and (30d) are as shown in FIG.
It is composed of a dipole antenna composed of two conductor rods (31) and (32) whose one ends are close to each other, and a reflector (33) arranged at a predetermined interval from the conductor rods (31) and (32). , 2
The gap between the conductor rods (31) and (32) is connected to the coaxial cable (35) via a balloon (matching transformer).
(See FIG. 3), and this coaxial cable (35) is connected to a switch (41) in the underfloor unit (40) described later. The length of the two conductor rods (31) and (32) is selected according to the frequency of the receiving channel, and the reflector (33) is a combination of the two conductor rods (31) and (32). It is longer than the length.

Then, the four antennas (30a), (30b), (30
c) and (30d) are shifted by 90 ° in the horizontal direction, and the antennas (30a) and (30b) are mounted before and after the ventilator (3) (in a direction parallel to the rails). 30c) and (30d) are mounted on the left and right (in the direction perpendicular to the rail) of the ventilator (4) next to the ventilator (3).

Here, the mounting state of the antenna to the ventilator will be described in detail. A plurality of ventilators (3), (4), (5)} are mounted on the roof (2) of the vehicle body (1). (3), (4), (5)} are so-called push-in type ventilators which function as a ventilator for pushing the outside air into the vehicle during traveling. Each of the ventilators (3), (4), (5) The four corners (3a), (4a) and (5a) are fixed to the roof (2) with bolts (23). In this case, each of the ventilators (3), (4), (5)} is mounted in a state insulated from the vehicle body (1).

Then, the two antennas (30a) and (30b) are mounted using the bolts (23) fixing the legs (3a) at the four corners of the ventilator (3). Further, two antennas (30c) and (30d) are mounted using bolts (23) fixing the four corner legs (4a) of the ventilator (4) next to the ventilator (3).

FIG. 3 and FIG. 4 show an enlarged view of how the antennas (30c) and (30d) are mounted on the ventilator (4).
Around the ventilator (4), a U-shaped cover (24) is attached with bolts (23). In this case, the cover (24) does not block the ventilation part (4b) of the ventilator (4). Then, one end of a connecting member (34) constituting the antennas (30c) and (30d) is fixed to the upper part of the cover (24), and the respective connecting members (34) are fixed.
A reflector (33) is fixed at a substantially central portion of the substrate, and conductor bars (31) and (32) are fixed at the other end. Here, the two conductor rods (31) and (32) are fixed to the connecting member (34) with a predetermined gap. The connecting member (34) is made of an insulating material. Further, in this example, the conductor rods (31) and (32) and the reflector (33) are formed of an angle material having an L-shaped cross section so that they can be easily attached.

Here, an interval H in the height direction between the upper part of each ventilator and the lower end of the reflector (33) is at least 15 mm, and the horizontal width L between each ventilator and the reflector (33) is at least the width. 20 mm, and height B of the reflector (33)
70 mm or more. In this case, the values of the height H and the width L of the ventilator and the height B of the reflector (33) are preferably larger in view of the characteristics of the antenna, but actually, the size of the equipment that can be mounted on the rooftop (2) is large. Is determined by standards such as the vehicle limit, and it is not possible to mount an antenna that is too large, and the antenna is limited to the above-mentioned value or a value slightly larger than this value.

Thus, the four antennas (30a), (30b),
Since (30c) and (30d) are installed, each antenna (30a), (30b), (30c), and (30d) can only receive radio waves in the direction where the conductor rods (31) and (32) are installed. And receive
Radio waves traveling from the other side (ventilator side) to the conductor rods (31) and (32) are shielded by the reflector (33), and the generation of standing waves due to the reflected radio waves can be suppressed. Therefore, 90
4 antennas (30a), (30
b), (30c) and (30d) can receive radio waves coming from almost all directions.

Then, the four antennas (30
a), (30b), (30c), and (30d), a switch (41) in an underfloor unit (40) suspended under the floor of the vehicle body (1)
With a coaxial cable (35). In this underfloor unit (40), equipment for teletext reception is stored,
The switch (41) selectively outputs a reception signal supplied from any antenna under the control of a determination circuit (44) described later. Then, the received signal output from the switch (41) is
A ghost reduction tuner (43) is supplied via a booster (42) to receive a television broadcast signal of a predetermined channel set in advance by the ghost reduction tuner (43). In this case, the ghost reduction tuner (43) uses the GC inserted during the vertical retrace period.
It performs ghost reduction of received broadcast signals using R signals, etc., and includes a ghost removal filter, a GCR signal extraction circuit, a comparison circuit, a control circuit, etc., together with a channel selection unit and an intermediate frequency amplification / demodulation unit. The reference signal is compared with a GCR signal that is distorted due to irregular reflection or the like, and a reflected wave signal is suppressed.

Here, in the present example, the television broadcast signal of a predetermined channel obtained by the ghost reduction tuner (43) is supplied to a discrimination circuit (44), and the television broadcast signal received by the discrimination circuit (44) is supplied to the discrimination circuit (44). The level of the included synchronization signal is determined, and the selection of the antenna line in the switch (41) is
A so-called diversity antenna is formed by obtaining a synchronization signal of the best level. in this case,
A timer circuit (45) is connected to the determination circuit (44), and the above-described level determination is performed every second under the control of the timer circuit (45). That is, the timer circuit (45) supplies a judgment control signal to the discrimination circuit (44) every time it counts a time corresponding to one second, and the discrimination circuit (44) sets the level every time the judgment control signal is supplied. A determination is made. Therefore, the switching of the antenna line by the switch (41) is performed at intervals of one second even when the radio wave condition is the worst, and every one second when the reception condition of any of the switched antennas is good. Synchronization signals of a certain level or more are detected by the level determination performed, and signals from the same antenna are continuously received for one second or more.

The television broadcast signal obtained by the ghost reduction tuner (43) is supplied to a teletext decoder (46). The teletext decoder (46) multiplexes the text and graphics multiplexed during the vertical blanking period of the broadcast signal. And the like. In this case, a plurality of teletext programs are transmitted by one-channel television broadcast signals, and when data of at least one screen of a predetermined teletext program set in advance is obtained, the teletext decoder (46) transmits the data to the teletext decoder (46). This data is stored in the connected memory (47). That is, the teletext decoder (46) has a circuit for judging whether or not each of the teletext screens received and obtained is a complete one. If it is determined that the data is a teletext program required by this data, it is stored in the memory (47).

In this case, transmission of data for one screen of a teletext program is normally performed in about 0.5 to 1 second. Therefore, when good reception can be performed continuously for at least about 0.5 to 1 second, one screen of teletext data can be received, and when a more favorable reception state continues, a plurality of screens (that is, one text broadcast program) can be received. Of all pages and a plurality of teletext programs).

Then, the data of the predetermined teletext program stored in the memory (47) in this way is sequentially read out to the teletext decoder (46), and the characters, figures, and the like indicated by the data are converted into video signals for image display. The video signal is output from the underfloor unit (40) using a coaxial cable. in this case,
This output video signal is a baseband video signal (ie, RF
Unmodulated video signal). In this example, a power supply circuit (48) is provided in the underfloor unit (40), and a DC low-voltage power supply is output from the power supply circuit (48).

Then, a coaxial cable for outputting a video signal from the underfloor unit (40) is connected to a three-way distributor (61) attached to the vehicle body (1) to supply an output video signal. Also,
The power output from the power supply circuit (48) is also a three-way distributor (61)
To supply. This three-way divider (61) has a built-in amplifier, amplifies the supplied baseband video signal by three times, and then performs three-way distribution. Thus, the gain of the input video signal becomes equal to the gain of the distributed output video signal. In this case, amplification is performed by the power supply output from the power supply circuit (48).

Then, of the first, second and third distribution outputs from the three distributors (61), the first distribution output is supplied to the first two distributors (71), and the second distribution output is supplied to the first two distributors (71). Supply to a connection terminal (62) provided on a connection surface on a first end (one end) side of the vehicle body (1),
The third distribution output is supplied to a connection terminal (63) provided on a connection surface on the second end (the other end) side of the vehicle body (1). Also,
The power supplied to the three dividers (61) is also supplied to the first two dividers (71).

The first splitter (71) has a built-in amplifier, amplifies the supplied baseband video signal by a factor of two, and then splits the signal into two. As in the case of the above-described three divider (61), the gain of the input video signal is equal to the gain of the distributed output video signal. In this case, amplification is performed by the power supplied from the power supply circuit (48) via the three divider (61).

Then, the first split output distributed by the first splitter (71) is supplied to a second splitter (72) connected to the subsequent stage, and the second split output is connected to the subsequent stage. It supplies to the thirteenth two-way distributor (83). In this case, the power supplied from the three dividers (61) is supplied to the second and thirteenth two dividers (72) and (83).

The second two-way divider (72) comprises a first two-way divider (71).
In the same manner as described above, the supplied baseband video signal is amplified by a factor of two, and then divided into two. The first distributed output is set to the television receiver (10
1), and the second distributed output is connected to the third
To the two distributors (73).

Hereinafter, similarly, the two distributors (73) connected to the subsequent stage,
(74), (75) ‥‥ (82), after amplifying the supplied baseband video signal by a factor of two, perform two distributions, and use the first distribution output for the corresponding television mounted in the vehicle. Supply to the receivers (103), (104), (105) ‥‥ (111),
A second distributor (74) connected to the subsequent stage,
(75), (76) ‥‥ (82). However, the second split output of the twelfth splitter (82) connected last is supplied to the television receiver (112).

Also in this case, the power supplied from the former two-divider is supplied to the television receiver and the latter two-divider connected from each two-divider.

Also, a television receiver (113) mounted in a vehicle is provided with a first distribution output of a thirteenth two-way distributor (83) connected to a second distribution output side of the first two-way distributor (71). Supply to
The second split output is connected to a fourteenth splitter (8
4) to supply.

Hereinafter, similarly, the two distributors (85) connected to the subsequent stage,
(86), (87) ‥‥ (93), after amplifying the supplied baseband video signal by a factor of two, perform two distributions, and use the first distribution output for the corresponding television mounted in the vehicle. Supply to the receivers (114), (115), (116) ‥‥ (123),
A second distributor (86) connected to the subsequent stage,
(87), (88) ‥‥ (93). However, the second distribution output of the 23rd two-way distributor (93) connected last is supplied to the television receiver (124).

Also in this case, the power supplied from the former two-divider is supplied to the television receiver and the latter two-divider connected from each two-divider.

The connection terminals (62) and (63) provided on the connection surface
Is connected to the video signal input terminal of the connected vehicle (not shown) when another vehicle not equipped with a tuner or the like is connected back and forth. A video signal can be supplied. In this case, the power required by the video distributors and the television receivers of the front and rear vehicles is supplied from a power supply circuit in each vehicle.

Next, a description will be given of an operation in the case of displaying a text broadcast image on the television receivers (101), (102), (103) ‥‥ (124) connected in this manner.

First, an operation of receiving a teletext broadcast and storing data of a required teletext program in a memory (47) connected to the teletext decoder (46) is performed. In this case, if the reception state of the television broadcast signal is good, the storage operation in the memory (47) is completed in a short time, but the service is actually performed when the vehicle (1) is running. Therefore, when the reception state temporarily becomes good and data of at least one screen of the teletext program required by the teletext decoder (46) is obtained, the data of the obtained screen is converted to The data is stored in the memory (47), and the previously stored data of the same page is updated to the newly received data.

In this case, the direction of the transmitting station as viewed from the vehicle (1) changes with traveling, but any of the four antennas (30a), (30b), (30c), and (30d) whose directions are different by 90 ° is satisfactory. Diversity antennas that determine whether or not reception is possible are configured. These antennas (30a), (30b), (30
c) and (30d) are sequentially connected to the tuner (43) by the switch (41), and the reception state of the ghost reduction tuner (43) is sequentially determined by the determination circuit (44). Connected to an antenna that can provide a suitable broadcast signal.

In this case, under the control of the timer circuit (45), the judgment of the reception state by the judgment circuit (44) is performed every second, and the receiving antenna is switched at least every second.
It is highly likely that at least one screen of data of a teletext program is obtained while receiving a signal from one antenna, and the receiving antenna is switched while receiving one screen of data. It is difficult for accidents to occur. That is, if the receiving antenna is switched while data for one screen is being received, the received data is temporarily interrupted at the time of the switching in the teletext decoder (46), and data for one screen is not completely obtained. , A reception error occurs. Here, transmission of data for one screen is usually performed in about 0.5 to 1 second, and in this example, the receiving antenna is switched at least every 1 second, so that a signal from one antenna is received. In the meantime, there is a high possibility that data for at least one screen of a teletext program is obtained, and the teletext data for at least one screen can be stored in the memory (47) and the teletext data can be sequentially updated.

Since the reception condition temporarily becomes good and the screen of the teletext program required by the teletext decoder (46) can be obtained only when the reception condition is very good, most of the stations are used. It is when the vehicle is stopped. That is, for example, in the case of a train running in the city center at each station stop, every two to three minutes, the train stops at the station for about several tens of seconds to one minute, and during this stop, it is possible to receive a text broadcast program for one screen or more And it is possible to receive teletext at a relatively high frequency.

When the teletext data can be taken into the memory (47) connected to the teletext decoder (46) in this manner, the video signal for reading the teletext program to be displayed at predetermined intervals and displaying the teletext is displayed. Is transmitted to the television receivers (101) to (124) via the distributors (61), (71) to (93), and the television receiver installed in the vehicle Teletext programs are displayed in (101) to (124). In this case, for example, a plurality of types of text broadcasting are sequentially displayed in a cycle of several minutes to several tens of minutes.

In the above-described embodiment, the receiving antennas are switched at least at intervals of 1 second or more. However, if the receiving antennas are switched at least at intervals of 1 sec. Similar effects can be obtained.
In this case, if the minimum switching time is shortened, it takes less time to search for a good reception antenna,
The possibility of occurrence of a reception error in which the antenna is switched while receiving one screen of teletext data increases. Conversely, if the minimum switching time is increased, the possibility of occurrence of a reception error in which the antenna is switched while receiving one screen of teletext data is reduced. It takes time. Therefore, it is best to set the minimum interval for switching the receiving antenna to about 1 second ± 0.5 seconds.

Further, in the above-described embodiment, only the teletext receiving equipment is installed. However, a video reproducing device such as a VTR may be provided to display the reproduced video alternately with the teletext program.

The receiving antennas consist of four antennas (30a), (3
0b), (30c) and (30d) constitute the diversity antenna, but the diversity antenna may be constituted by more antennas.

Further, in the above-described embodiment, the receiving system is installed on the train, but other moving objects (cars, ships, etc.)
Also applicable to

Furthermore, the present invention is not limited to the above-described embodiment, but may take various other configurations.

〔The invention's effect〕

According to the present invention, the receiving antenna is rarely switched during reception of one screen of a teletext, the occurrence of a reception error is reduced, and the reception of the teletext by the diversity antenna can be improved. With the antenna device having a relatively simple configuration, it is possible to favorably receive teletext on a mobile object.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention, FIG. 2 is a partially cutaway perspective view showing a state of mounting the system of the embodiment on a vehicle body, and FIG. 3 shows a main part of the embodiment. FIG. 4 is a side view showing a main part of one embodiment. (1) is a car body, (3), (4) ‥‥ (8) is a ventilator, (30a), (30b), (30c), (30d) are antennas,
(40) is an underfloor unit, (41) is a switch, (43) is a ghost reduction tuner, (46) is a teletext decoder, (47) is a memory, (48) is a power circuit, and (61) is a three-way distributor. , (62) and (63) are connection terminals, (71) and (72).
(93) is a two-way distributor, and (101), (102) ‥‥ (124) are television receivers.

────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Torao Aozuka 6-7-35 Kita-Shinagawa, Shinagawa-ku, Tokyo Inside Sony Corporation (56) References JP-A-1-235489 (JP, A) JP-A Sho 63-13536 (JP, A) (58) Field surveyed (Int. Cl. ⁶ , DB name) H04N 7/025-7/088 H04B 1/16

Claims (1)

(57) [Claims] 1. A plurality of antennas mounted on a mobile object, antenna switching means for selecting one of the plurality of antennas, and a reception state of a signal from the antenna selected by the antenna switching means. Is determined at intervals of 1 second ± 0.5 seconds, and when the reception state is not good, the determination means for controlling the antenna switching means so as to switch the antenna; and a signal from the antenna selected by the antenna switching means. A teletext for a mobile object comprising: a television broadcast receiving tuner for demodulation; a teletext decoder for demodulating a teletext signal from an output of the television broadcast receiving tuner; and a display device for displaying the output of the teletext decoder. Broadcast receiving system.