JPH0834445B2 - Transmitter - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention is suitable for being provided on a mobile body side when communication is performed between a fixed station and a mobile body such as an automobile or an aircraft using a geostationary satellite, for example. Regarding a transmitter.

[Outline of Invention]

According to the present invention, in a transmission device in which a main unit and a transmission unit section are connected by a single coaxial cable and transmission is performed in a burst, a signal having a frequency different from a transmission signal is used as a control signal via the coaxial cable. To the transmitter unit part, and only when this is detected, the amplifier is supplied with an idling current, and then the transmission signal is supplied to the transmitter unit part, thereby providing a power-saving transmitter device. To do.

[Conventional technology]

A communication system has been considered in which two-way communication is performed between a mobile body such as an aircraft, a ship, or an automobile and a ground communication center using a geostationary satellite (US Pat. No. 4,35.
(See No. 9,733, No. 16, 1982).

Figure 3 shows the outline of this satellite communication system.
(1) is a terrestrial communication center, (2), (3) and (4) are geostationary satellites, and (5) and (6) are aircraft and automobiles as examples of mobile units equipped with communication terminals.

In this communication system, the positions of the mobile units (5) and (6) can be notified from the communication center to the mobile units (5) and (6), and specific messages can be transmitted and received.

For example, the information on the position of the mobile body is communicated as follows.

That is, first, the satellite (2)-(4) is transmitted from the ground-based communication center (1) via the three geostationary satellites (2)-(4).
The inquiry signal is transmitted to the entire area that can be covered in (4).

The mobile units (5) and (6) receiving the interrogation signal receive the signals specific to the mobile unit in a short time and at high output with the satellite (2).
To (4) to the communication center (1). At the communication center (1), the positions of the mobile bodies (5) and (6) are obtained by triangulation using a computer. Then, the position information of the mobile units (5) and (6) is sent from the communication center (1) to
It transmits to the mobile bodies (5) and (6) via the satellites (2) to (4) together with the identification signals of the mobile bodies (5) and (6). The mobile units (5) and (6) detect the identification signal and obtain their own position information.

In this case, the communication between the communication center (1) and the satellites (2) to (4) is performed at 5 to 7 GHz, while the transmission from the mobile units (5) and (6) is 1.6 GHz and the reception is 2.5 GHz. Made in.

By the way, a terminal system provided in a mobile body includes a main unit having a keyboard and a display, and a transceiver unit, and both units are equipped with a microcomputer (hereinafter referred to as a microcomputer).

FIG. 4 shows an example of installation when this terminal system is attached to a truck, and the main unit (7) is placed near the driver's seat for the user to input keys and to see the display. On the other hand, the transceiver unit (8) is connected to the transceiver antenna (9) and is provided at a position exposed to the outside, for example, on the roof.

The main unit (7) and the transceiver unit (8) are connected by a communication cable (10) which is, for example, an RS-232C cable.

In order to divide the terminal system into two units in this way, the antenna (9) must be provided at a position exposed to the outside because it is directed to the satellite. Moreover, a relatively high output is required for transmitting to the satellite, but if the antenna (9) and the transceiver unit (8) are separated from each other, the transmission output will be attenuated to that extent, resulting in insufficient output. Therefore, it is necessary to arrange the transceiver unit and the antenna as close to each other as possible.

[Problems to be solved by the invention]

By the way, in the terminal system divided into two units provided in the mobile body as described above, if only an amplifier that does not require an idling current, for example, a class C amplifier is used in the transmission unit section of the transceiver unit, A configuration as shown in FIG. 5 can be considered. That is, the direct-current power supply (not shown) provided in the main unit (7) charges the charging capacitor (51) of the transmission unit section (40) via the cable (10), and then the transmission signal is transmitted. It is conceivable that this amplifier (50) will be turned on by supplying this to the class C amplifier (50) via the cable (10), and the charging voltage of the capacitor (51) will be supplied to the amplifier (50) as a power source. To be

However, in order to perform high-quality transmission, the transmission unit section needs an idling current instead of the class C amplifier or in addition to the class C amplifier, for example, class A or
A class AB amplifier may be used. Even when a transmission signal is not supplied to this amplifier, a voltage is supplied from the power supply, an idling current is supplied, and power is consumed.

In order to save this power consumption, it is conceivable to apply an idling current only when necessary. For example, as shown in FIG. 6, when a class A or class AB amplifier (52) is provided in front of the class C amplifier (50), the class A or class AB amplifier (52) and the capacitor (51) are connected to each other. And a control switch (53), and a cable (54) for a control signal is provided between the main unit (7) and the transmission unit section (40). The transmitted signal is then amplified (5
Prior to being supplied to 2), a control signal is supplied to a switch (53) via a cable (54), which is turned on to supply a voltage to an amplifier (52) to flow an idling current. Then, the transmission signal is supplied to the amplifier (52), and the switch (53) is also turned off at the end of the transmission signal to stop the idling current.

However, when the main unit and the transmission unit are separated from each other as in the above-mentioned terminal system, it is uneconomical to add a control signal cable as shown in FIG. It is also complicated in terms of composition.

[Means for solving problems]

The present invention relates to a main unit (30), a transmission unit section (32), a single coaxial cable (31) connecting the main unit (30) and the transmission unit section (32), and a transmission unit section (32). ) Charging capacitor (15)
And an amplifier (21) requiring an idling current, and means (17) (18) (19) for detecting a control signal and supplying an idling current to the amplifier (21).

[Action]

A DC voltage is supplied to the transmission unit section (32) by the main unit (30) and the capacitor (15) is charged. Then, before sending the transmission signal to the transmission unit section (32), the control signal is transmitted to the transmission unit section (3).
2) sent to. In the transmission unit section (32), the control signal is detected and an idling current is passed through the amplifier (21). After that, the transmission signal is the main unit (30)
Is supplied from the transmitting unit section (32) to a high output by the amplifier (21) of the transmitting unit section (32) and sent from the transmitting antenna.

〔Example〕

FIG. 1 is an embodiment of the present invention and shows an example in which it is applied to a terminal system provided on the mobile side of the communication system described above.

In the figure, (30) is a main unit, (32) is a transmission unit part, and both are connected by one coaxial cable (31).

In the main unit (30), (11) is, for example, 1.
A transmission signal generation circuit for generating a 6 GHz transmission signal (see FIG. 2D), and (14) is a control signal generation circuit for generating a 32 KHz control signal (see FIG. 2B), for example. Further, (12) is a timing signal generation circuit,
In response to a transmission request from the user, first, the control signal generation circuit (14) outputs the control signal, and then the transmission signal generation circuit (11) outputs the transmission signal.

(13) is, for example, a 60 V DC power source (see FIG. 2A),
(22) is a diode for preventing mixing of the control signal from the signal generation circuit (14), (23) is a capacitor, (2
4) is a choke coil.

Further, in the transmitting unit (32), (27) is a choke coil, (29) is a backflow prevention diode, and (15) is a charging capacitor charged by the DC power supply (13) of the main unit (30). . (34) is an inductor provided so that the control signal is not dropped to ground, (28)
Is a DC blocking capacitor, (16) is a low-pass filter that passes only low-frequency control signals, (17) is a detection circuit that detects the control signal from the signal generation circuit (14), and (18) is a control signal detection circuit. This is a switch drive circuit that turns on the switch (19) when detected by (17). Further, (20) is a regulator for adjusting the power supply voltage supplied to the amplifier (21).

When there is a transmission request from the user, a control signal (see FIG. 2B) is output from the control signal generation circuit (14) in accordance with a command signal from the timing signal generation circuit (12). The output control signal is supplied to the detection circuit (17) via the coaxial cable (31) and the low-pass filter (16) and detected. Then, the drive circuit (1
The switch (19) is turned on by (8) (Fig. 2C).
The charge voltage of the capacitor (15) as the power supply voltage via the switch (19) and the regulator (20).
It is supplied to the class or class AB amplifier (21). Then, an idling current flows through this amplifier (21). Then, after a lapse of time from when the idling current starts to flow until the amplifier (21) becomes in an operation state sufficient to perform class A or class AB operation, the timing signal generation circuit (12) outputs a command signal to generate a transmission signal. It is output to the circuit (11) and this circuit (1
A transmission signal (see FIG. 2D) is output from 1). The output transmission signal is supplied to the amplifier (21) via the capacitor (25), the coaxial cable (31), the capacitor (26) and the high-pass filter (33), and is amplified.

When the generation of the transmission signal from the signal generating circuit (11) ends, the generation of the control signal from the signal generating circuit (14) also ends according to the command signal from the timing signal generating circuit (12). Then, the switch drive circuit (18) turns off the switch (19), the power supply voltage to the amplifier (21) is cut, and the idling current stops flowing to the amplifier (21).

The present invention is not limited to the terminal system of the communication system as described above, but can be applied to any transmitting device that requires an idling current, for example, a class A or class AB amplifier is used.

〔The invention's effect〕

According to the present invention, the control signal is supplied to the transmission unit section through the coaxial cable, and when this is detected, an idling current flows in the class A or class AB amplifier,
After that, the transmission signal is supplied to the amplifier via the coaxial cable, and the idling current does not flow in the amplifier when it is not transmitting, so power consumption can be increased without adding a cable for the control signal. There is an effect that can be saved.

[Brief description of drawings]

FIG. 1 is a diagram showing an embodiment of the present invention, FIG. 2 is a diagram showing timing of each signal, FIG. 3 is a diagram showing an outline of a satellite communication system, and FIG. 4 is a configuration diagram of its user terminal system. FIG. 5 is a diagram showing a case where a class C amplifier is used, and FIG. 6 is a diagram showing a case where a class A or class AB and class C amplifier is used. (30) is the main unit, (32) is the transmission unit section,
(31) is a coaxial cable, (11) is a transmission signal generation circuit,
(12) is a timing signal generation circuit, (13) is a DC power supply,
(14) is a control signal generation circuit, (15) is a charging capacitor, (16) is a low-pass filter, (17) is a detection circuit, (18) is a switch drive circuit, (19) is a connection switch, and (20) is The regulator (21) is a class A or class AB amplifier.

Claims (1)

[Claims] 1. A main unit and a transmission unit section are connected by a single coaxial cable to perform transmission in bursts, wherein the transmission unit section requires an amplifier and a charging unit that require an idling current. A capacitor is provided, a DC voltage is supplied from the main unit to the transmission unit section through the coaxial cable, the capacitor is charged, and a transmission signal is sent from the main unit to the transmission unit section. When a control signal is sent to the transmission unit section and this control signal is detected, the amplifier unit in the transmission unit section supplies the charging voltage of the capacitor as a power source to supply an idling current, and then the transmission signal is transmitted. It is designed to be supplied from the main unit to the transmission unit section. The transmission device.