DE19646192C2 - RF modulator - Google Patents

Description

The present invention relates to an RF modulator according to the preamble of the An saying 1. It is used to convert a composite video signal and a sound signal reproduced, for example, by a video tape recorder be in a television broadcast signal, as well as for mixing this signal with a Antenna input signal. In particular, the invention relates to a connection arrangement HF modulator.

In general, an RF modulator of this type has a modulation part for Um set a composite video signal or the like, which from egg is reproduced in a video tape recorder or similar device Television broadcast signal, and a booster amplifier part for amplifying an antenna input signal and for mixing the signal with the television broadcast signal, to output the composite signal. In addition, a PLL circuit (Pha control loop) for changing the carrier frequency for the modulation in one composite video signal, which is supplied from the outside.

A known RF modulator of the type mentioned above is known from DE 43 35 488 known. It is explained in more detail below.

Fig. 7 shows the back of a circuit board of a conventional RF modulator without PLL circuit, Fig. 8 shows the connection arrangement of Fig. 7. In addition, Fig. 9 shows the back of a circuit board of a conventional RF modulator with PLL circuit.

In the RF modulator without a PLL circuit according to Fig. 7 and 8 is a Montageflä surface of a circuit board 11 a is divided into a left half region and a right half area with in-the middle region thereof shielding plate 12. The components of a booster amplifier part 13 and a modulator part 14 are arranged in the left and right zones, respectively. The modulator part 14 without the PLL circuit only contains a modulator circuit 14 a. In addition, on the right side of the circuit board 11 a, a video signal input port 1 , an audio signal input port 2 , a power supply port for a modulator (Md + B) 3 , an idle port 4 and a power supply port for a booster (BST + B) 5 , in a single Row trained. The connections 1 to 4 and the connection 5 are connected to the modulator part 14 and the booster amplifier part 13 via non-crossing line patterns. In addition, only in the right zone is a side portion 111 in the horizontal direction from the circuit board 11 a, and the connections 1 to 5 are arranged in this area 111 in the form of a single row, so that external connections are connected to these connections 1 to 5 , In addition, an ANT.IN connector 17 (antenna input) and an ANT.OUT connector 18 (antenna output) are connected directly to the booster amplifier part 13 , the ANT.IN connector 17 being connected to the line pattern 17 a.

In comparison, in the case of the RF modulator with PLL circuit shown in FIG. 9, a circuit board 19 b is similarly divided into a left half zone and a right half zone with a shielding plate 12 located between them. A booster amplifier part 13, a Mo dulatorteil 14 from a modulator circuit 14 a and a PLL TIC 15, and a crystal oscillator (X-TAL) 16 are mounted in the left and in the right zone. Five leads 1 to 5 are located on the right side of the circuit board 1 b, and also an SDA (data) connector 6 , a CLK (clock) connector 7 , an idle connector 8 and a tuning connector 9 for Setting a carrier frequency from the outside as connections for the PLL circuit 15 on the left side of the board 11 b added. Ports 1 through 9 are on a single line. The common connections 1 to 5 are connected to the modulator part 14 and the booster amplifier part 13 via line patterns similar to FIG. 7, and the connections 6 to 9 are connected to the PLL circuit 15 via line patterns. In the circuit board 11 b with a PLL circuit there is a section 112 from the board which extends from a right side section to the left side in the horizontal direction, the connections 1 to 9 being located on this section 112 ,

The following are intended to be solved by the present invention Problems are explained.

In the conventional RF modulator with PLL circuit, the connections 6 to 9 for the PLL circuit on the side of the booster amplifier part 13 are additionally in a single row, as shown in FIG. 9, and the line patterns are also cut Connecting the connections 6 to 9 to the PLL circuit the line patterns which connect the connections 1 to 5 to the modulator part 14 and the booster amplifier part 13 . The problem thus arises that stray components of a signal current flowing between the PLL circuit 15 and the connections 6 to 9 via the line patterns reach the booster amplifier part 13 and exert a negative influence on the RF-modulated signal, which produces an output signal of the HF Is modulator.

More specifically, since in the example of FIG. 9, the PLL connections 6 to 9 and their line pattern are in the vicinity of an ANT.IN connector 17 of the booster amplifier part 13 and a vibration component of 4 MHz of the crystal oscillator 16 is close to that Fre quency of a video signal, a beat disturbance is generated in the video signal. In addition, since a frequency divider of the PLL circuit 15 divides the 4 MHz signal, for example, into a 7.81 kHz signal from the audio band, there is a buzzing or whistling in the tone of the television signal, for example at this frequency.

Due to the different number of connections, the circuit boards 11 a and 11 b without or with PLL circuit under different shape. So you have two types of circuit boards that have to be made with different metal shapes, which makes the manufacturing more expensive. In addition, since the connections 1 to 9 are arranged in a single row, the housing body for leading out these connections differs in an arrangement without a PLL circuit from an arrangement with a PLL circuit. Therefore, since the metal molds used to manufacture the housing bodies also differ, additional cost increases arise.

From EP 432 052 A2 an RF modulator is known in which the frequency Stabilization of the carrier frequency PLL circuits are used.

The invention has for its object to provide an RF modulator which has a detrimental effect on the RF-modulated signals in particular is avoided or at least reduced.

This object is achieved by the features specified in claim 1.

A mounting surface of a circuit board is through a shield plate divided. The components of the modulation circuit and the PLL circuit are arranged in a first zone of the circuit board, and a first on final group of the modulation circuit and the booster amplifier circuit and a second connection group of the PLL circuit are in a double row installed, and the components of the booster amplifier circuit are in another zone.

According to the invention, the component mounting surface of the circuit board (divided by the shielding plate), the components are the modu lation circuit and the PLL circuit arranged in one zone, and the first connection group of the modulation circuit and the booster amplifier circuit and the second connection group of the PLL  Circuit are arranged in a double row housing, the second connector group of the PLL circuit not near the Booster amplifier circuit comes, which makes it possible to get one adverse influence on video and audio signals, that is, on image and To avoid sound.

It is also sufficient for the circuit board without PLL circuit, at only the first signal group is mounted, and the circuit Circuit board with PLL circuit, in which the first and the second connection group are assembled, form both connection groups in such a way that they only stand out from the part that is on the side of the modula tion circuit is located. This makes it possible to connect groups form with the same outer shape, so that you have circuit boards can produce with one and the same metal mold. If you also an opening for leading out the first connection group and the second connection group on the side of the housing body, you can lead the first connection group out through this opening, if the RF modulator has no PLL circuit and consequently only the first connection group is brought out.

In the following, exemplary embodiments of the invention are described with reference to the Drawings explained. Show it:

Figure 1 is a descriptive representation of the back of a circuit board as an embodiment of the inventive RF modulator.

FIG. 2 shows a view of a connection arrangement according to FIG. 1;

FIG. 3 shows a side view of the connection arrangement according to FIG. 2;

FIG. 4 shows a top view of the RF modulator according to FIG. 1;

Fig. 5 is a front view of the RF modulator of Fig. 1;

Fig. 6 is a block diagram of the RF modulator of Fig. 1;

Fig. 7 is a descriptive illustration of the back of a circuit board of a conventional RF modulator without a PLL circuit;

Fig. 8 is a view of the connector assembly of FIG. 7, and

Fig. 9 is a descriptive illustration of the back of a circuit board of a conventional RF modulator with a PLL circuit device.

According to Fig. 1 is a mounting surface of a circuit board 11 is divided into a left half region and a right half-area, being located in the middle of a shield board 12. A booster amplifier part 13 and a modulation part 14 , consisting of a modulation circuit 14 a and a PLL circuit 15 and a crystal oscillator 16 , are arranged in the left and right zones, respectively. Furthermore, an ANT.IN (antenna input) connector 17 and an ANT.OUT (antenna output) connector 18 are attached directly to the booster amplifier part 13 , the ANT.IN connector 17 being connected to a line pattern 17 a. As shown in Fig. 2, on the right side of the circuit board 14 are housed in a double-row housing or component: a first connection group in the form of a single-row arrangement, consisting of a video signal input connector 1 , an audio signal input connector 2 , a power supply connector for a modulator (Md + B) 3 , an idle connection 4 and a power supply connection for a booster (BST + B) 5 , further a second connection group in the form of a single row arrangement, consisting of an SDA (data) connection 6 , a CLK (clock) ) Connection 6 , an idle connection 8 and a tuning connection 9 for setting a carrier frequency from outside, the latter connections being provided for the PLL circuit 15 . The connections 1 to 5 are connected to the modulation circuit 14 and the booster amplifier circuit 13 , the connections 6 to 9 are connected to the PLL circuit 15 .

As shown in FIG. 3, the first group of connections 1 to 5 , like the second group of connections 6 to 9, is bent in an L-shaped manner such that the respective points lie in one and the same row, which extends in the horizontal direction, whereby the outer connections can be easily connected and the other ends can be soldered to the line patterns on the rear side with the help of through-holes of the circuit board 11 . Furthermore, an opening between the first group of connections 1 to 5 and the second group of connections 6 to 9 and between the individual connections of the second group of connections 6 to 9 is fixed by a molded part 19 . As also shown in FIGS. 4 and 5, a connector 20 for the VTR.TU (video tape recorder tuner) is attached to one side of the booster amplifier part 13 .

As also shown in Figs. 4 and 5, the circuit board 11 , on which the components of the respective circuits, the group of terminals 1 to 9 and the like are mounted in the manner described above, is inserted into a housing body 21 such that the Group of connections 1 to 9 and the connectors 17 , 18 and 20 protrude outwards. If an opening 21 a for leading out the first group of connections 1 to 5 and the second group of connections 6 to 9 is formed on one side of the housing body 21 , there is the possibility of the group of connections 1 to 5 through the opening 21 a lead out if the RF modulator has no PLL circuit, so that then only the first group of connections 1 to 5 is led out.

Next, the circuit structure will be explained with reference to FIG. 6. The power supply connections 3 and 5 and the like are not shown in the figure.

As can be seen from FIG. 6, in the booster amplifier part 13, an RF signal input via an antenna input terminal 17 and amplified by an RF amplifier 131 is passed to the antenna output terminal 18 and also to the VTR.TU terminal 20 . The branched-off to the side of the antenna output terminal 18 RF signal is further amplified by an RF amplifier 133 and then mixed with a video and audio mixed signal (RF signal) from the modulation part 14 by a mixing circuit 134, and connection to the antenna output 18 given.

In the modulation part 14 , a composite video signal input from a VTR (video tape recorder) or the like via the video input terminal 1 is input through a clamp circuit 141 and a white limiter circuit 142 to a video modulation and sound mixing circuit 143 and modulated with a carrier which is generated by one Video carrier generator 144 is supplied, and it is mixed with the RF signal of a sound signal from an attenuator 149 at the same time, so as to generate an RF signal of the composite video signal and the sound signal. This RF signal is passed through a low-pass filter (TPF) 145 to the mixing circuit 134 of the booster amplifier 13 .

In addition, a sound signal input from a video tape recorder (or other device) passes through the audio input terminal 2 to a sound carrier generator / FM modulation circuit 148 after passing the signal through an attenuator 146 and a pre-emphasis circuit 147 to receive a signal from the PLL circuit 15 to be modulated and thereby form an RF signal. This sound signal is given via the attenuator 149 to the video modulation and sound mixing circuit 143 and mixed with the video signal. Both the video carrier generator 144 and the sound carrier generator FM modulation circuit 148 have a voltage controlled oscillator (VCO).

In the PLL circuit 15 , the crystal oscillator (X-TAL) 16 supplies a 4 MHz signal via a reference signal generator, and this signal is divided into 1/256 to 1/2 by a frequency divider 151 and sent to a phase comparator 152 for the video signal and given a phase comparator 156 for the sound signal. In the variable frequency divider 153 and 155 for video or sound, the respective frequency division ratios are set in accordance with the respective carrier for video and audio via the SDA connection (data connection) 6 , and the signals from the video carrier generator 144 and the sound carrier generator / FM modulation circuit 148 are shared. In the phase comparators 152 and 156 , the phase differences between the signal from the frequency divider 151 and the signals from the variable frequency plates 153 and 154 are detected. Then the respective phase differences from the low-pass filters (TPF) 154 and 157 are converted into a voltage, and this voltage is given to the associated VCO of the video carrier generator 144 or the sound carrier generator circuit / FM modulation circuit 148 , in order in this way to Set frequencies of the respective carriers for video and audio.

It is with such an RF modulator with a PLL circuit possible to increase the number of channels of the carrier in a simple manner increase. As a result, it is also possible to correspond to the case that the carrier frequency for a destination address is different.

As explained above, a component is according to the invention area of a circuit board through a shield plate divided, components of a modulation circuit and a PLL Circuits are placed in a zone, a first group of An connect the modulation circuit and a booster amplifier circuit and a second group of connections of the PLL circuit at the same time housed in a double row housing. The second Connection group of the PLL circuit is therefore not in the  Proximity of the booster amplifier circuit, so that a detrimental influence on Video and audio signals are prevented.

In the case of a circuit board without a PLL circuit, in which only the first connection group is provided, and with a circuit board with a PLL circuit in which the first and the second connection group before seen, it is sufficient to train both groups, whereby possibly only the part of the modulation circuit to the outside stands. This makes it possible to unify the outer shape of the boards Lich execute what the manufacture of the boards with only one Metal mold cheaper. If an opening to lead out the first Extension group and the second extension group on the side of one Housing body is formed, you can only the first Lead the connection group through this opening if an HF Modulator without PLL circuit with only the first connection group is available. So you can have a uniform housing body for use both circuit variants, which ver the total production endorses.

Claims (2)

1. RF modulator with a modulation circuit ( 14 a) for modulating a composite video signal and a sound signal, which are fed to the outside, with a variable carrier frequency to output an RF signal, a PLL circuit ( 15 ) for changing the Trägerfre frequency of the modulation circuit based on an externally supplied control signal, and a booster amplifier circuit (13) for amplifying nes ei externally supplied to the antenna input signal and for mixing the signal with the modulated from the modulation circuit HF-Si gnal to a mixed signal output, characterized characterized in that a component mounting surface of a circuit board ( 11 ) of egg ner shield plate ( 12 ) is divided into two zones, that components of the modulation circuit ( 14 a) and the PLL circuit ( 15 ) are arranged in one zone of the circuit board that a first connection group ( 1-5 ) of the modulation circuit ( 14 a) and de r booster amplifier circuit ( 13 ) and a second connection group ( 6-9 ) of the PLL circuit are mounted in a double row, that components of the booster amplifier circuit ( 13 ) are arranged in the other zone of the circuit board, and that the first connection group ( 1- 5 ) and the second connection group ( 6-9 ) are arranged in one zone of the circuit board, in which the components of the modulation circuit ( 14 a) and the PLL circuit ( 15 ) are arranged. 2. RF modulator according to claim 1, characterized, that the connections of the two connection groups in pairs perpendicular to Component mounting surface are aligned.