JP2540819B2 - Receiving machine - Google Patents

Description

TECHNICAL FIELD The present invention relates to a receiver suitable for application to a satellite broadcast receiver capable of switching and receiving satellite broadcast signals of, for example, ku band and c band.

[Outline of Invention]

According to the present invention, in a receiver capable of switching and selecting a plurality of receiving bands, the AFT voltage is corrected in accordance with the switching of the receiving bands, so that all the receiving bands are adjusted to a just tuning state. Is.

[Conventional technology]

Conventionally, as a receiver for satellite broadcasting, ku band (12GHz
Band = 11.7 to 12.2 GHz) or c band (4 GHz band = 3.7 to
Those that can receive satellite broadcasting signals of 4.2 GHz) have been proposed. FIG. 4 shows such a receiver.
In the figure, ku or c band satellite broadcast signals S _BS from the broadcast satellite (1) are BS antennas (2K) and (2
It is supplied to the S / U converters (3K) and (3C) via C). The S / U converters (3K) and (3C) perform frequency conversion, and both ku band and ku band are 950 to 1450M.
Hz signal S _BS ′. That is, S / U converter (3K),
The frequencies (first local frequency) of the local signal for frequency conversion in (3C) are 10.75 GHz and 5.15 GHz, respectively.
It is fixed to.

In addition, the signal S _BS ′ from the S / U converters (3K) and (3C)
Are supplied to the K-side and C-side terminals of the changeover switch (4), respectively. The changeover switch (4) is switched by a microcomputer (hereinafter referred to as “microcomputer”) (6) based on the operation of the user on the operation panel (5), and when the ku band and the c band are selected, the K side is selected. And C
It is switched and connected to the side.

The signal S _BS ′ from the changeover switch (4) is supplied to the frequency converter (7). In this frequency converter (7), the signal S _BS ′ of 950 to 1450 MHz is converted into an intermediate frequency signal of 402.78 MHz. Then, this intermediate frequency signal is supplied to the FM detection circuit (8) for detection, and a composite signal So of the video signal and the FM audio signal is taken out from this FM detection circuit (8).

In this case, tuning is performed by changing the frequency (second local frequency) of the local signal S _L supplied from the PLL circuit (9) to the frequency converter (7). The control of the PLL circuit (9) is performed by the microcomputer (6) based on the operation of the user on the operation panel (5).

Further, a voltage Eo (so-called AFT voltage) indicating a change in the carrier frequency Fo of the intermediate frequency signal is obtained from the detection circuit (8), and this voltage Eo is supplied to the non-inverting input terminal of the operational amplifier (10). The inverting input terminal of the operational amplifier (10) is supplied with the offset voltage Vo from the mover of the variable resistor (11), and the output side of the operational amplifier (10) has a difference voltage Es between the voltage Eo and the offset voltage Vo. Is obtained.

The differential voltage Es from the operational amplifier (10) is supplied to the comparator (12) and compared with the voltages _{VL to VH} that define the dead zone. still,
The offset voltage Vo described above is set so that the differential voltage Es becomes an intermediate value between the voltages V _L and V _H when the carrier frequency Fo of the intermediate frequency signal is fo (402.78 MHz) during reception of the c band, for example. ing.

When V _L ≤ Es ≤ V _H , the microcomputer (6) from the comparator (12)
For example, the high level “1” signal is not supplied to the up terminal UP and the down terminal DOWN of the local signal S _L supplied from the PLL circuit (9) to the frequency converter (7) without any change. It When Es <V _L , the comparator (12)
For example, a high level “1” signal is supplied to the up terminal UP of the microcomputer (6), and the frequency of the local signal S _L supplied to the frequency converter (7) from the PLL circuit (9) is sequentially increased, The carrier frequency Fo of the intermediate frequency signal is sequentially increased. On the other hand, when Es> V _H, a high level “1” signal is supplied from the comparator (12) to the down terminal DOWN of the microcomputer (6), and the frequency converter (7) is supplied from the PLL circuit (9).
The frequency of the local signal S _L supplied to
The carrier frequency Fo of the intermediate frequency signal is gradually lowered. Therefore, the AFT operation is performed such that the difference voltage Es is within the voltages V _{L to} V _H and the carrier frequency Fo of the intermediate frequency signal that is clogged is fo (402.78 MHz). That is, it is automatically adjusted so as to be in the just tuning state.

[Problems to be solved by the invention]

By the way, in the example of FIG. 4, the offset voltage Vo supplied to the operational amplifier (10) is, as described above, the difference voltage Es is the voltage when the carrier frequency Fo of the intermediate frequency signal is fo during reception of the c band. It is set to an intermediate value between V _L and V _H. For example, the solid line a in FIG. 5 shows changes in the voltage Eo with respect to the carrier frequency Fo of the intermediate frequency signal when the c band is received, and the offset voltage Vo is set as shown. As a result, at the time of receiving the c band, FIG.
As shown in, the AFT operation is properly performed so that the carrier frequency Fo of the intermediate frequency signal becomes fo, and the just tuning state is adjusted.

However, as described above, the first local frequency of the c band is higher than the frequency of the satellite broadcast signal S _BS , while the first local frequency of the ku band is lower than the frequency of the satellite broadcast signal S _BS , and the first local frequency of the c band and the ku band is The polarities of the video signals are opposite. That is, the bias of the energy distribution of the signal is different.
Therefore, when the ku band is received, the voltage Eo changes with respect to the carrier frequency of the intermediate frequency signal as shown by the broken line b in FIG. As a result, when the ku band is received, an erroneous AFT operation is performed so that the carrier frequency Fo of the intermediate frequency signal is lower than fo by Δf, for example, about 1.2 MHz, as shown in FIG. 6B, and the just tuning state is not adjusted. .

In view of such a point, the present invention is to adjust to the just tuning state in all the reception bands.

[Means for solving problems]

The present invention is premised on a receiver capable of switching and selecting a plurality of reception bands, for example, c band and ku band. Further, in the present invention, a means for correcting the AFT voltage Eo is provided, and the AFT voltage is corrected according to the switching of the reception band.

For example, when switching reception from the c band to the ku band,
In response to this switching, the offset voltage Vo is increased by a predetermined value.

[Action]

For example, when switching the reception from the c band to the ku band, the AFT voltage Eo increases by a predetermined value as described above. As in the above configuration, the offset voltage Vo
Is increased by a predetermined value, the increased amount of the AFT voltage Eo is offset. Therefore, the AFT operation is correctly performed even when the reception is switched from the c band to the ku band.

〔Example〕

An embodiment of the present invention will be described below with reference to FIG. In FIG. 1, parts corresponding to those in FIG. 4 are designated by the same reference numerals, and detailed description thereof will be omitted.

In the figure, a resistor (21) is connected between the variable resistor (11) and ground, and the connection point of these variable resistor (11) and resistor (21) is connected to the collector of the npn-type transistor (22). The emitter of this transistor (22) is grounded.

In addition, a signal which becomes a high level “1” and a low level “0” at the base of the transistor (22) from the microcomputer (6) via the resistor (23) when receiving the c band and the ku band, respectively.
Transistor (22) when Sc is received and c-band is received
Is turned on, while the transistor (22) is turned off when the ku band is received.

Further, the position of the mover of the variable resistor (11) is such that when the c-band reception (transistor (22) is on) and the carrier frequency Fo of the intermediate frequency signal is fo, the difference voltage Es is the voltage V _L and the voltage V _H.
The offset voltage Vo is set so as to have an intermediate value of. Furthermore, the value of the resistor (21) is such that when the ku band is received (the transistor (22) is off) and the carrier frequency Fo of the intermediate frequency signal is fo, the difference voltage Es is equal to the voltage V _L and
The offset voltage Vo is set so as to be an intermediate value of V _H.

 Others are the same as those in the example of FIG.

In this example, the transistor (2
The signal Sc supplied to the base of 2) becomes high level "1", and the transistor (22) is turned on. Therefore, the offset voltage Vo obtained at the mover of the variable resistor (11) is
When the carrier frequency Fo of the intermediate frequency signal is fo during reception in the c band, the difference voltage Es has a value that is an intermediate value between the voltages V _L and V _H. Therefore, during the reception of the c-band, the AFT operation is properly performed so that the carrier frequency Fo of the intermediate frequency signal becomes fo, and the just tuning state is adjusted.
On the other hand, when the ku band is received, the signal Sc supplied to the base of the transistor (22) becomes low level “0”, and the transistor (22) is turned off. Therefore, the offset voltage Vo obtained at the mover of the variable resistor (11) is the difference voltage when the carrier frequency Fo of the intermediate frequency signal is fo when the ku band is received.
It becomes a value such that Es becomes an intermediate value between the voltages V _L and V _H. Therefore, even when the ku band is received, the AFT operation is properly performed so that the carrier frequency Fo of the intermediate frequency signal becomes fo, and the just tuning state is adjusted.

As described above, according to this example, the AFT operation is correctly performed during the reception of the c band and the reception of the ku band, and the just tuning state is adjusted.

Next, FIG. 2 shows another embodiment of the present invention. In FIG. 2, parts corresponding to those in FIG. 4 are designated by the same reference numerals, and detailed description thereof will be omitted.

In the figure, the offset voltage Vo obtained at the mover of the variable resistor (11) is, for example, 1/2 of the voltage Eo when the carrier frequency Fo of the intermediate frequency signal is fo (402.78 MHz) at the time of receiving the c band. The value of.

The differential voltage Es obtained from the operational amplifier (10) is A / D.
It is supplied to the microcomputer (6) via the converter (31).

Further, (32) is a memory including, for example, an MNOS transistor. In this memory (32), for example, at the time of manufacture,
A voltage Lc equal to the difference voltage Es obtained when the carrier frequency Fo of the intermediate frequency signal is fo when the c band is received, and a difference voltage Es obtained when the carrier frequency Fo of the intermediate frequency signal is fo when the ku band is received The voltage Lku equal to is written.

This example is configured as described above, and the AFT operation is performed according to the flowchart shown in FIG. 3 under the control of the microcomputer (6).

That is, a timer is set at the start, and it is determined in step whether or not a predetermined time, for example, 100 msec has elapsed. This predetermined time is the time taken for the voltage Eo to stabilize.

When the predetermined time has elapsed, the reception band is determined in step. When the reception band is the c band, the comparison voltage Vc is set to the voltage Lc written in the memory (32) in step. On the other hand, when the reception band is the ku band, the comparison voltage Vc is set to the voltage Lku written in the memory (32) in step.

When the comparison voltage Vc is set, the difference voltage Es supplied from the A / D converter (31) is measured in step.

When the difference voltage Es is measured, the magnitude of the difference voltage Es and the comparison voltage Vc is determined in a step. When Es <Vc, the reception band is determined in step, and when the reception band is c band, the reception frequency is 10 in step.
It is controlled so that it is lowered by 0 KHz, and when the reception band is the ku band, the reception frequency is increased in steps.
It is controlled to increase by 100 KHz. In this case, the signal is for the c-band 3.7-4.2 GHz satellite broadcast signal S _BS .
S _BS ′ changes from 950 to 1450 MHz, and ku band 11.
Signal S _BS ′ is 1450 for satellite broadcast signal S _{BS of 7} to 12.2 GHz
Change to ~ 950MHz. Therefore, when receiving the c band, ku
The PLL circuit (9) is controlled similarly during band reception, and the frequency of the local signal S _L supplied to the frequency converter (7) is increased by 100 KHz, and eventually the carrier frequency Fo of the intermediate frequency signal is increased by 100 KHz. . When Es> Vc, the reception band is determined in step, and when the reception band is c band, the reception frequency is determined in step.
It is controlled to increase by 100 KHz, and when the reception band is the ku band, the reception frequency is controlled to decrease by 100 KHz in steps. Also in this case,
The PLL circuit (9) is controlled in the same manner during the reception of the c band and during the reception of the ku band, and the frequency of the local signal S _L supplied to the frequency converter (7) is lowered by 100 KHz. Fo is lowered by 100 KHz.

The reception frequency is controlled as described above, or Es =
When it is Vc, the timer is set at the step, and the step is returned to the step. Then, the same operation as described above is performed, and finally Es = Vc is set.

In this way, in this example, the frequency of the local signal S _L is controlled during reception of the c band and during reception of the ku band, and Es =
It is set to Vc. That is, the AFT operation is properly performed so that the carrier frequency Fo of the intermediate frequency signal becomes fo, and the just tuning state is adjusted.

Therefore, according to this example, it is possible to obtain the same effects as those of the first example.

〔The invention's effect〕

According to the present invention described above, the AFT voltage is corrected according to the switching of the reception band, so that there is an advantage that the AFT operation is correctly performed in all the reception bands and the just tuning state is adjusted.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention, FIG. 2 is a block diagram showing another embodiment of the present invention, FIG. 3 is a flow chart for explaining the operation of the example of FIG. 2, and FIG. Is a configuration diagram of a conventional example, and FIGS. 5 and 6 are diagrams for explaining the configuration. (3K) and (3C) are S / U converters, (4) is a changeover switch, (5) is an operation panel, (6) is a microcomputer, (7) is a frequency converter, (8) is an FM detection circuit,
(9) is a PLL circuit, (10) is an operational amplifier, (11) is a variable resistor, (12) is a comparator, (21) is a resistor, and (22) is np.
An n-type transistor, (31) is an A / D converter, and (32) is a memory.

Claims (1)

(57) [Claims] 1. A receiver capable of receiving video signals of different reception bands from an artificial satellite in common and switching and selecting them, inputs an output of FM detection of an intermediate frequency signal to one input end of an operational amplifier, and The offset voltage is supplied to the other input terminal, and the AFT
A receiver characterized by correcting an offset for each voltage reception band.