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Claims  |
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What is claimed is:
1. A satellite signal receiving apparatus comprising an outdoor unit, a
channel selector and a transmission line connecting therebetween, wherein
said outdoor unit comprises:
a receiving means for receiving vertically polarized radiation and
horizontally polarized radiation, respectively, transmitted from an
artificial satellite;
a frequency converting means for converting either one of said vertically
polarized radiation and said horizontally polarized radiation output from
said receiving means into transmission signal having a predetermined
frequency band and outputting said transmission signal to said
transmission line;
a source voltage extracting means for extracting a source voltage
superposed over a pulse train by said channel selector and received
therefrom via said transmission line;
a smoothing means for smoothing said source voltage extracted by said
source voltage extracting means;
a constant-voltage means for converting said source voltage smoothed by
said smoothing means into a predetermined voltage and for supplying said
predetermined voltage to each component of said outdoor unit;
a pulse train detecting means for detecting a pulse train from said source
voltage extracted by said source voltage extracting means to generate a
detection signal; and
a polarized radiation signal switch control means for switching said
vertically and horizontally polarized radiation signals to be converted in
frequency by said frequency converting means and output to said
transmission line in accordance with said detection signal generated by
said pulse train detecting means.
2. A satellite signal receiving apparatus according to claim 1, wherein
said frequency converting means further comprises horizontally polarized
radiation signal amplifier means and vertically polarized radiation signal
amplifier means, each amplifier means including a high electron mobility
transistor each of which is selectively driven in accordance with a source
voltage supplied from said polarized radiation signal switch control
means.
3. A satellite signal receiving apparatus according to claim 2, wherein
said polarized radiation signal switch control means includes at least one
resistor, a Zener diode and at least one transistor, and selectively
supplies a source voltage generated by said constant-voltage means to said
vertically polarized radiation signal amplifier means and said
horizontally polarized radiation signal amplifier means on the basis of
said detection signal from said pulse train detecting means.
4. A satellite signal receiving apparatus according to claim 1, wherein
said frequency converting means further comprises a medium frequency
amplifier means which amplifies said transmission signal, and output via
said source voltage extracting means and an output terminal means to said
one transmission line.
5. A satellite signal receiving apparatus according to claim 1, wherein
said source voltage extracting means includes a condenser which outputs
said transmission signal via an output terminal means to said one
transmission line.
6. A satellite signal receiving apparatus according to claim 1, wherein
said source voltage extracting means includes a coil which extracts said
source voltage fed via an output terminal from said channel selector.
7. A satellite signal receiving apparatus according to claim 1, wherein
said smoothing means includes a condenser and a coil which smoothes said
extracted source voltage, to generate a source voltage for driving said
outdoor unit.
8. A satellite signal receiving apparatus according to claim 1, wherein
said source voltage extracting means extracts said source voltage and
outputs to said pulse train detecting means which includes resistors and
an operational amplifier and outputs said detection signal in accordance
with a level of said source voltage.
9. A satellite signal receiving apparatus comprising an outdoor unit, a
channel selector and one transmission line connecting therebetween,
wherein said channel selector comprises:
a tuning means coupled via said one transmission line to said outdoor unit
for extracting a transmission signal having a predetermined frequency from
said transmission signal fed via said one transmission line from said
outdoor unit and demodulating said extracted transmission signal;
an operating means for designating said frequency of said transmission
signal to be demodulated by said tuning means;
a source voltage generating means for generating source voltage to be
supplied to said outdoor unit via said one transmission line;
a polarized radiation signal designating means for determining whether a
polarized radiation signal is to be a vertically polarized radiation
signal or a horizontally polarized radiation signal, said polarized
radiation signal being converted in frequency by a frequency converting
means;
a pulse train superposing means for superposing a predetermined pulse train
over said source voltage according to said polarized radiation signal
designated by said polarized radiation signal designating means; and
a source voltage output means for outputting said source voltage passed
through said pulse train superposing means to said one transmission line,
said outdoor unit receiving and extracting said source voltage and
detecting said pulse train which switches said polarized radiation signal.
10. A satellite signal receiving apparatus according to claim 9, wherein
said source voltage output means receives said source voltage passed
through said pulse train superposing means and outputs said source voltage
via a coil to an input terminal means.
11. A satellite signal receiving apparatus according to claim 9, wherein
source voltage output means receives said transmission signal via an input
terminal means from said outdoor unit and feed said transmission signal
via a condenser to said tuning means.
12. A satellite signal receiving apparatus according to claim 9, wherein
said pulse train superposing means includes a switch which switches
between a first status and a second status in response to said polarized
radiation signal designating means.
13. A satellite signal receiving apparatus according to claim 9, wherein
said pulse train superposing, means includes means for changing width of
said pulse train superposed on said source voltage.
14. A satellite signal receiving apparatus according to claim 9, wherein
said pulse train superposing means includes means for changing frequency
of said pulse train superposed on said source voltage.
15. A satellite signal receiving apparatus according to claim 9, wherein
said polarized radiation signal is polarized in one of a horizontal and
vertical plane, and wherein said plane of said polarized radiation signal
corresponds to said channel selected by said tuning means, and wherein
said pulse train superposing means includes a switch which is actuated in
response to at least one of said channel signal designating means and said
tuning means.
16. A satellite signal receiving apparatus according to claim 12, wherein,
said switch is in said first status, on condition that said horizontally
polarized radiation signal is designated by said polarized radiation
signal designating means, and said source voltage is output from said
source voltage generating means to said source voltage output means
without being treated by said pulse train superposing means.
17. A satellite signal receiving apparatus according to claim 12, wherein,
when said switch is in said second status on condition that said
vertically polarized radiation signal is designated by said polarized
radiation signal designating means, said pulse train superposing means
superposes said pulse train output from a pulse generating means over said
source voltage output from said source voltage generating means, said
source voltage with said pulse train superposed thereover is output to
said source voltage output means.
18. A satellite signal receiving apparatus according to claim 12, wherein,
said pulse train superposing means includes at least one transistor, said
at least one transistor receiving said pulse train from said pulse train
superposing means and selectively turns from a first status to a second
status when said switch is in said second status, said at least one
transistor being provided with at least one resistor for dropping said
source voltage down to a predetermined voltage determined by a breakdown
voltage of a Zener diode when said at least one transistor is in said
second status.
19. A satellite signal receiving apparatus according to claim 12, wherein
when said switch is in said second status, said pulse train superposing
means superposes said predetermined pulse train from said pulse train
superposing means over said source voltage, and changes said source
voltage to a predetermined voltage by said pulse train, and outputs said
predetermined voltage to said source voltage output means.
20. A satellite signal receiving apparatus according to claim 12, wherein
said switch is in said second status on condition that said polarized
radiation signal designating means selects said vertically polarized
radiation signal, said channel selector supplies to said outdoor means
said source voltage generated by said source voltage generating means with
said predetermined pulse train superposed thereover.
21. A satellite signal receiving apparatus according to claim 12, wherein
said switch is in said first status and said polarized radiation signal
designating means selects said horizontally polarized radiation signal,
said channel selector supplies to said outdoor unit said source voltage
generated by said source voltage generating means without being treated by
said pulse train superposing means.
22. A satellite signal receiving apparatus comprising:
an outdoor unit including;
a receiving means for receiving vertically polarized radiation and
horizontally polarized radiation, respectively, transmitted from an
artificial satellite, and
a frequency converting means for converting either one of said vertically
polarized radiation and said horizontally polarized radiation output from
said receiving means into a transmission signal having a predetermined
frequency band and outputting said transmission signal to a transmission
line;
a channel selecting means including:
a tuning means coupled via said transmission line to said outdoor unit for
extracting said transmission signal having a predetermined frequency from
said transmission signal fed via said transmission line from said outdoor
unit and demodulating said extracted transmission signal,
an operating means for designating said predetermined frequency of said
transmission signal to be demodulated by said tuning means,
wherein said channel selecting means further includes;
a source voltage generating means for generating a source voltage to be
supplied to said outdoor unit via said transmission line,
a polarized radiation signal designating means for determining whether a
polarized radiation signal is to be said vertically polarized radiation or
said horizontally polarized radiation, said polarized radiation signal
being converted in frequency by said frequency converting means,
a pulse train superposing means for superposing a predetermined pulse train
over said source voltage according to said polarized radiation signal
designated by said polarized radiation signal designating means, and
a source voltage output means for outputting said source voltage passed
through said pulse train superposing means to said transmission line, said
outdoor unit further includes:
a source voltage extracting means for extracting said source voltage passed
through said pulse train superposing means and received from said
transmission line,
a smoothing means for smoothing said source voltage extracted by said
source voltage extracting means,
a constant-voltage means for converting said source voltage smoothed by
said smoothing means into a predetermined voltage and for supplying said
predetermined voltage to each component of said outdoor unit,
a pulse train detecting means for detecting a pulse train from said source
voltage extracted by said source voltage extracting means, and
a polarized radiation signal switch control means for switching said
polarized radiation signal to be converted in frequency by said frequency
converting means and output to said transmission line in accordance with
said detecting by said pulse train detecting means. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention relates to a satellite signal receiving apparatus that
receives the vertically and horizontally polarized radiations sent from an
artificial satellite.
Known communication satellites send out transmission radiation by
alternately changing the plane of polarization of the transmission
radiation for each adjacent channel, so that communication frequencies are
effectively used. For example, JCSAT by Nihon Tsushin Eisel Co., Ltd.,
Super Bird by Uchu Tsusin Co., Ltd. and other communication satellites are
available.
The satellite signal receiving apparatus for receiving radiation from such
known communication satellites is disclosed in Laid-open Japan Patent
Application No. 61-195094. The satellite signal receiving apparatus
includes a receiving antenna located outdoors and provided with two
converters and a switch. The two converters convert horizontally and
vertically polarized radiation signals to the transmission signals having
a specified frequency band, respectively. The switch selectively outputs
either one of the transmission signals having the frequency converted by
each converter. By controlling the switch at the side of the channel
selecting unit located indoors, the desired polarized radiation signal is
obtained at the side of the channel selecting unit.
In the aforementioned satellite signal receiving apparatus a signal line is
provided for transmitting the switch driving signal from the channel
selecting unit to the switch of the receiving antenna. A transmission line
is also provided for coupling the receiving antenna and the channel
selecting unit and for transmitting received signals. Therefore, when the
satellite signal receiving apparatus is installed, the signal line and the
transmission line have to be coupled separately. The installation work of
the satellite signal receiving apparatus is thus complicated.
To solve such problem, the inventors of this invention developed the
control over the switch without using the additional signal line for
controlling the switch. Specifically, by providing a switch circuit at the
channel selecting unit and a control circuit at the receiving antenna, the
switch can be controlled without the signal line. The switch circuit
switches the source voltage to be supplied to the receiving antenna into
high or low source voltage, and the control circuit controls the switch
according to the magnitude of the source voltage supplied from the channel
selecting unit to the receiving antenna.
Generally in the satellite signal receiving apparatus, power source is
supplied from the channel selecting unit to the receiving antenna via the
transmission line for transmitting the received signals from the receiving
antenna to the channel selecting unit. Therefore, when the plane of the
polarization is switched and controlled by changing the magnitude of the
source voltage, the receiving antenna and the channel selecting unit can
be coupled only by the single transmission line. The installation work is
thus simplified.
When the magnitude of the source voltage is changed, however, the
constant-voltage circuit having input voltage with wide variations allowed
is required for the receiving antenna, so that the converter can be
operated with both the high and low source voltages. When the high source
voltage is supplied to the receiving antenna, the input voltage to the
constant-voltage circuit is dropped so much that the heat amount released
from the constant-voltage circuit increases. Since raised temperature
deteriorates the noise factor and other electric characteristics of the
converter, the configuration of the converter has to be enlarged, or other
actions against heat release are required.
Another problem is that the source voltage fed into the constant-voltage
circuit decreases according to the length of the transmission line. The
length of the transmission line varies with the position of the satellite
signal receiving apparatus or other conditions. The greater the difference
between the high and low source voltages is, the more precisely the
difference between the source voltages can be determined regardless of the
length of the transmission line, and the more precisely the switch can be
switched and controlled. When the channel selecting unit outputs to the
receiving antenna the high source voltage much higher than the low source
voltage and the transmission line is short, however, the constant-voltage
circuit has to receive extremely high source voltage. Consequently, when
the polarized radiation signal is switched by changing the source voltage
to be supplied to the receiving antenna, the size of the source voltage
output from the channel selecting unit is difficult to set.
SUMMARY OF THE INVENTION
An object of this invention is to provide a satellite signal receiving
apparatus that receives vertically and horizontally polarized radiation
signals at the side of a receiving antenna and selectively outputs either
one of the vertically and horizontally polarized radiation signals, in
which polarized radiation signals are switched without being affected by
released heat or other conditions and without using a separate signal
line.
To solve these objects the present invention provides a satellite signal
receiving apparatus comprising a outdoor unit and a channel selector. The
outdoor portion comprises a receiving portion and a frequency converting
circuit. The receiving portion receives vertically polarized radiation and
horizontally polarized radiation, respectively, transmitted from an
artificial satellite. The frequency converting circuit converts either one
of the vertically polarized radiation and the horizontally polarized
radiation output from the receiving portion into transmission signal
having a specified frequency band, and outputs the transmission signal to
a transmission line.
The channel selector comprises a tuning circuit and an operating portion.
The channel selecting circuit is coupled via the transmission line to the
outdoor unit. The tuning circuit extracts transmission signal having a
specified frequency from transmission signals fed via the transmission
line from the outdoor unit, and demodulates the transmission signal. The
operating portion designates from the outside the frequency of the
transmission signal to be demodulated by the tuning circuit.
The channel selecting portion further comprises a source voltage generating
circuit, a polarized radiation signal designating portion, a pulse train
superposing circuit, and a source voltage output circuit. The source
voltage generating circuit generates source voltage to be supplied to the
outdoor unit. The polarized radiation signal designating portion
determines whether polarized radiation signal is to be vertically
polarized radiation signal or horizontally polarized radiation signal. The
polarized radiation signal is converted in frequency by the frequency
converting circuit and output to the transmission line. The pulse train
superposing circuit superposes a specified pulse train over the source
voltage according to the polarized radiation signal designated by the
polarized radiation signal designating portion. The source voltage output
circuit outputs source voltage passed through the pulse train superposing
circuit to the transmission line.
The outdoor portion further comprises a source voltage extracting circuit,
a smoothing circuit, a constant-voltage circuit, a pulse train detecting
circuit, and a polarized radiation signal switch control circuit. The
source voltage extracting circuit extracts source voltage from the
transmission line. The smoothing circuit smooths the source voltage
extracted by the source voltage extracting circuit. The constant-voltage
circuit converts the source voltage smoothed by the smoothing circuit into
specified voltage and supplies the specified voltage to each component of
the outdoor portion. The pulse train detecting circuit detects a pulse
train from the source voltage extracted by the source voltage extracting
circuit. The polarized radiation signal switch control circuit switches
the polarized radiation signal to be converted in frequency by the
frequency converting circuit and outputs to the transmission line
according to the detection by the pulse train detecting circuit.
In the channel selecting portion of the aforementioned satellite signal
receiving apparatus, the source voltage is generated in the source voltage
generating circuit. The pulse train superposing circuit superposes a pulse
train over the source voltage according to the type of the polarized
radiation signal designated by the polarized radiation signal designating
portion. The polarized radiation signal designating portion designates the
vertically polarized radiation signal or the horizontally polarized
radiation signal. The source voltage output circuit supplies power source
to the outdoor unit by outputting the source voltage passed through the
pulse train superposing circuit to the transmission line for transmitting
transmission signal.
The outdoor unit receives power source from the channel selector. In the
outdoor unit, the source voltage extracting circuit extracts source
voltage from the transmission line. The smoothing circuit smooths the
source voltage extracted by the source voltage extracting circuit. The
constant-voltage circuit converts the smoothed source voltage into
specified voltage. The power source having constant voltage is supplied to
the outdoor unit for driving each component therein. The pulse train
detecting circuit detects the pulse train from the source voltage
extracted by the source voltage extracting circuit. According to the
result of the detection by the pulse train detecting circuit, the
polarized radiation signal switch control circuit switches the polarized
radiation signal. The polarized radiation signal is converted in frequency
in the frequency converting circuit and output to the transmission line.
The transmission signal is thus transmitted to the channel selector
corresponding to the type of the polarized radiation signal designated by
the polarized radiation signal designating portion.
Instead of switching the value of the source voltage to be supplied to the
outdoor unit, the satellite signal receiving apparatus of this invention
superposes the pulse train over the source voltage and switches the type
of the polarized radiation signal provided by the outdoor unit.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1A is an electric circuit diagram showing a circuit structure of a
receiver in a satellite signal receiving apparatus embodying the present
invention.
FIG. 1B is an electric circuit diagram showing a circuit structure of an
outdoor unit in the satellite signal receiving apparatus.
FIG. 2 is a schematic diagram showing the structure of the satellite signal
receiving apparatus.
FIGS. 3A through 3K are time charts explaining the operation of the
receiver and the outdoor unit.
FIG. 4 is an electric circuit diagram showing the modification of the
circuit structure shown in FIG. 1A.
FIG. 5 is an electric circuit diagram showing the modification of the
circuit structure shown in FIG. 1B.
FIG. 6 is an electric circuit diagram showing another modification of the
circuit structure shown in FIG. 1A.
FIG. 7 is an electric circuit diagram showing another modification of the
circuit structure shown in FIG. 1B.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
FIG. 2 shows a parabolic antenna 1 of offset type as a receiving antenna. A
reflecting mirror 2 of the parabolic antenna 1 is attached via a support 5
to a post 4 set upright on a mount 3 for fixing the parabolic antenna 1 on
the roof or on the ground. The elevation angle and the azimuth angle of
the reflecting mirror 2 can be adjusted with the support 5. One end of a
bracket 7 is coupled to the support 5 and the other end of the bracket 7
supports the outdoor unit 6 such that a radiation introducing portion 6a
is positioned at the focus of the reflecting mirror 2. The outdoor unit 6
receives vertically polarized radiation and horizontally polarized
radiation collected from a communication satellite by the reflecting
mirror 2. On the other hand, the outdoor unit 6 is low noise blockdown
converter (LNB), which converts either of the received vertically and
horizontally polarized radiations into the transmission signal having a
predetermined frequency band, for example 1 GHz band for output.
One end of a transmission line 8 of a coaxial cable is coupled to an output
terminal 6b of the outdoor unit 6. The other end of the transmission line
8 is coupled to a channel selector 10 located adjacent to a television set
9 indoors. Therefore, the transmission signal is output from the outdoor
unit 6 through the transmission line 8 into the channel selector 10. The
channel selector 10 includes a channel selecting key 11 as an operating
portion and is coupled via a connection line 12 to the television set 9.
From the transmission signals from the outdoor unit 6, the channel
selector 10 as the channel selecting portion extracts the transmission
signal having the frequency corresponding to the frequency of the channel
designated by the channel selecting key 11. The channel selector 10 then
demodulates the extracted transmission signal. In this embodiment
television signal is the transmission signal. The television signal
demodulated by the channel selector 10 is fed via the connection line 12
into the television set 9. The channel selector 10 is also provided with a
polarized radiation selecting key 13 for determining whether the
transmission signal from the outdoor unit 6 is to be a vertically
polarized radiation signal or a horizontally polarized radiation signal.
The channel selector 10 is now explained in detail with reference to FIG.
1A. The channel selector 10 has an input terminal 20 for coupling to the
transmission line 8 and an output terminal 21 for coupling to the
connection line 12. The transmission signal is fed from the outdoor unit 6
via the transmission line 8 and the input terminal 20 into the channel
selector 10. The transmission signal is further fed through a source
separation filter 22 into a tuning circuit 23 as a tuning circuit. In the
tuning circuit 23 the television signal having the frequency corresponding
to the frequency of the channel designated by the channel selecting key 11
is demodulated. The demodulated television signal is fed through the
output terminal 21 and the connection line 12 into the television set 9.
Commercial electric power is introduced via an AC plug 24 into the channel
selector 10. In the channel selector 10 the voltage of the introduced
commercial electric power is dropped by a transformer 25. The commercial
electric power with the dropped voltage is all rectified through a
rectifier circuit 28 and is fed via a smoothing condenser 27 into a
constant-voltage circuit 28. The constant-voltage circuit 28 as the source
voltage generating circuit generates source voltage Vb necessary for
supplying power to the inside circuits of the channel selector 10 and the
outdoor unit 6. The source voltage Vb generated by the constant-voltage
circuit 28 is supplied to the tuning circuit 23 and other pertinent
components of the channel selector 10. At the same time, the source
voltage Vb is transmitted via a pulse train superposing circuit 29, the
source separation filter 22 and the input terminal 20 described later into
the transmission line 8. The source separation filter 22 as a source
voltage output circuit receives the transmission signal via the input
terminal 20 from the outdoor unit 6 and feeds the transmission signal via
a condenser C1 to the tuning circuit 23. At the same time, the source
separation filter 22 receives the source voltage passed through the pulse
train superposing circuit 29 and outputs the source voltage via a coil L1
to the input terminal 20.
The pulse train superposing circuit 29 includes a switch 29a which switches
on or off in cooperation with the polarized radiation selecting key 13. As
shown in FIG. 1A, when the switch 29a is off, on the condition that the
horizontally polarized radiation signal is selected and designated by the
polarized radiation selecting key 13, the source voltage Vb is output from
the constant-voltage circuit 28 to the source separation filter 22 without
being treated. Conversely, when the switch 29a is on, on the condition
that the vertically polarized radiation signal is designated by the
polarized radiation selecting key 13, the pulse train output from a pulse
generating circuit 30 described later is superposed over the source
voltage Vb output from the constant-voltage circuit 28. The source voltage
Vb with the pulse train superposed thereover is thus output to the source
separation filter 22. The aforementioned specified voltage is 7.5 V, the
half of the Vb in this embodiment, and is, for example, selectively the
two-thirds or less of Vb, at which a comparator 60 described later can
identify the existence of pulse.
As shown in FIG. 1A, the pulse train superposing circuit 30 also includes
transistors TR1 and TR2. When the switch 29a is on, the transistor TR1
receives an output pulse from the pulse generating circuit 30 and turns on
and off. The transistor TR2 is provided with resistors R1 and R2 for
dropping the source voltage Vb down to the specified voltage determined by
the breakdown voltage of a Zener diode D1 when the transistor TR1 is on.
As shown in FIGS. 3C through 3E, when the switch 29a is off, the source
voltage Vb from the constant-voltage circuit 28 is output to the source
separation filter 22 without being treated. When the switch 29a is on, the
output pulse from the pulse generating circuit 30 is superposed over the
source voltage Vb. Specifically, the source voltage Vb is dropped down to
the specified voltage by the output pulse, and is output to the source
separation filter 22.
As shown in FIG. 1A, the pulse generating circuit 30 includes a known
astable multivibrator 31, a known monostable multivibrator 32 and an
inverting circuit 33. The astable multivibrator 31 includes NAND circuits
N1, N2, resistors R3, R4, and a condenser C2. The monostable multivibrator
32 includes NAND circuits N3, N4, a resistor R5, and a condenser C3. The
inverting circuit 33 includes resistors R7, R8 and a transistor TR3. As
shown in FIG. 3A, the astable multivibrator 31 generates the pulse signal
having the predetermined frequency of, for example, between 20 kHz and 30
kHz. As shown in FIG. 3B, the monostable multivibrator 32 generates the
pulse signal remaining at a low level for a predetermined time period, 3
to 5.mu. sec. in this embodiment, from the leading edge of the output
pulse from the astable multivibrator 31. As shown in FIG. 3C, the
inverting circuit 33 generates the pulse signal such that the output pulse
from the monostable multivibrator 32 is inverted and is superposed over
the source voltage Vb. The pulse generating circuit 30 acts upon receiving
source supply +B1 via a Zener diode D2 from the constant-voltage circuit
28.
The outdoor unit 6 is now explained in detail with reference to FIG. 1B.
The vertically and horizontally polarized radiations are collected from
the communication satellite to the radiation introducing portion 6a, and
are further introduced through a cylindrical waveguide 40 to probes 41 and
42 as the receiving portion for receiving the radiation at each plane of
polarization. The output signals from the probes 41 and 42 are composed of
the vertically and horizontally polarized radiation signals. The output
signals are fed into a vertically polarized radiation signal amplifier
circuit 43 and a horizontally polarized radiation signal amplifier circuit
44, respectively, which are composed of a known low noise amplifier
circuit composed of a high electron mobility transistor. The high electron
mobility transistor acts by receiving positive and negative source
voltages. According to the positive source voltage supplied from a
polarized radiation signal switch control circuit 45 described later,
either one of the vertically and horizontally polarized radiation signal
amplifier circuits 43 and 44 is selectively driven.
As shown in FIG. 1B, the output signals output from the vertically and
horizontally polarized radiation signal amplifier circuits 43 and 44 are
fed via a mixer circuit 46 into a high frequency amplifier circuit 47, and
are further amplified therethrough. Subsequently, the amplified output
signals are mixed with the output signal output from a local oscillator
circuit 49 by a mixer circuit 48, and are converted into the transmission
signal having a predetermined frequency band, for example, 1 GHz band. The
transmission signal is amplified by a medium frequency amplifier circuit
50, and is output via a source separation filter 51 and the output
terminal 6b to the transmission line 8. In this embodiment, the vertically
polarized radiation signal amplifier circuit 43, the horizontally
polarized radiation signal amplifier circuit 44, the mixer circuit 46, the
high frequency amplifier circuit 47, the mixer circuit 48, the local
oscillator 49 and the medium frequency amplifier circuit 50 compose a
frequency converting circuit.
As shown in FIG. 1B, the source separation filter 51 composes the source
voltage extracting circuit, and outputs the transmission signal via a
condenser C11 toward the output terminal 6b. At the same time the source
separation filter 51 extracts via a coil L11 the source voltage fed via
the output terminal 6b from the channel selector 10. The extracted source
voltage is smoothed in a smoothing circuit 52 composed of a condenser C12
and a coil L12. The source voltage is fed into a constant-voltage circuit
53, is converted to the specified voltage, 10 V in this embodiment. The
specified voltage is optional between 5 V and 10 V, which is suitable for
activating the high frequency amplifier circuit 47, the medium frequency
amplifier circuit 50 and a negative voltage generating circuit 56
described later. Subsequently, the specified voltage is further smoothed
by a smoothing condenser 54 to form a source voltage +B2 for driving the
outdoor unit 6. In the embodiment the source voltage extracted by the
source separation filter 51 is first smoothed by the smoothing circuit 52
and is then fed into the constant-voltage circuit 53. As aforementioned,
in the embodiment the pulse train is superposed over the source voltage
supplied from the side of the channel selector 10 as desired. If the
source voltage with the pulse train superposed thereover is directly fed
into the constant-voltage circuit 53, the constant-voltage circuit 53
outputs unstable output voltage. If the source voltage with the pulse
train superposed thereover is smoothed beforehand by the smoothing circuit
52, the source voltage is added to the comparator 60 without being
affected by the constant-voltage circuit 53. The outdoor unit 6 is also
provided with the negative voltage generating circuit 56, which generates
negative source voltage for driving the vertically and horizontally
polarized radiation signal amplifier circuits 43 and 44. Therefore, the
negative source voltage generated by the negative voltage generating
circuit 56 is constantly supplied to the vertically and horizontally
polarized radiation signal amplifier circuits 43 and 44.
As shown in FIG. 1B, the comparator 60 includes resistors R11 through R14
and an operational amplifier OP1. As shown in FIG. 3F, the comparator 60
outputs the signal of high level when the source voltage has the specified
value or less, 8 V in this embodiment. The specified value is set greater
than the half of Vb and less than Vb. The source voltage extracted by the
source separation filter 51 is fed into the comparator 60. The output
signal output from the comparator 60 is fed into a known monostable
multivibrator 61. As shown in FIG. 1B, the monostable multivibrator 61
includes resistors R15, R16, condensers C13, C14 and NAND circuits N11,
N12. As shown in FIG. 3G, the pulse signal generated by the monostable
multivibrator 61 stays at high level for a specified time period from the
leading edge of the output signal output from the comparator 60. The
specified time period is shorter than the time period obtained by
subtracting the pulse width of the pulse generating circuit 30 from the
period of the astable multivibrator 31. When the oscillating frequency of
the astable multivibrator 31 is 20kHz, its period is 50.mu. sec. When the
pulse width of the pulse generating circuit 30 is 3.mu. sec., the
specified time period may be shorter than 50.mu. sec. minus 3.mu. sec.,
47.mu. sec. In this embodiment the specified time period is 40.mu. sec.
The output signal output from the monostable multivibrator 61 is fed into a
smoothing circuit 62. The smoothing circuit 62 is composed of an integral
circuit and a voltage follower. As shown in FIG. 1B, the integral circuit
includes a resistor R17 and a condenser C15, and the voltage follower
includes an operational amplifier OP2. The output signal is smoothed in
the integral circuit, and is output via the voltage follower. As shown in
FIG. 3H, the smoothed output signal is output from the smoothing circuit
62, and is fed into a wave-shaping circuit 63. As shown in FIG. 1B, the
wave-shaping circuit 63 includes resistors R18, R19 and an operational
amplifier OP3. As shown in FIGS. 3H and 3I, when the output signal output
from the smoothing circuit 62 has a specified level or more, the output
signal from the wave-shaping circuit 63 has high level. The specified
level is 8 V in this embodiment, and may be set greater than the half of
Vb and less than Vb. After being shaped, the output signal is fed from the
wave-shaping circuit 63 into the polarized radiation signal switch control
circuit 45.
As shown in FIG. 1B, the polarized radiation signal switch control circuit
45 includes resistors R20 through R23, Zener diode D11, and transistors
TR11 through TR13. As shown in FIGS. 3I and 3J, when the output signal
from the wave-shaping circuit 63 has high level, the polarized radiation
signal switch control circuit 45 supplies the source voltage +B2 generated
by the constant-voltage circuit 53 as a positive source voltage to the
vertically polarized radiation signal amplifier circuit 43. As shown in
FIGS. 3I and 3K, when the output signal from the wave-shaping circuit 63
has low level, the polarized radiation signal switch control circuit 45
supplies the source voltage +B2 generated by the constant-voltage circuit
53 as a positive source voltage to the ho | | |
