NL1017506C2 - Audio in video embedding system converts analog video and analog audio signals and uses modular circuits to combine them digitally before reconverting combined signal to analog form - Google Patents

Abstract

The system consists of a video module (30) and a number of audio modules (40). The analog video signal (31) is converted (32) to digital form. The audio inputs (41) are each fed to analog to digital converters (42) in the audio modules. All the digital audio signals are chained through the audio modules to a logical combining circuit (33) in the video module. The combined signal is reconverted (34) to analogue form.

Description

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Title: Audio-in-video embedding system

The present invention relates in general to professional equipment for processing digital video and audio signals. In addition, it is desirable to have means that combine audio signals with video signals into a combined signal. Current technology makes it possible to add multiple channels of digital audio to the digital video. It is therefore possible to provide a device for combining video signals and audio signals, hereinafter also referred to as "embedder", with a large number of audio inputs; depending on the number of channels of audio to be combined with the video, one or more of those audio inputs are then used. However, in most cases only a limited number of the audio inputs 15 will be used. An embedder that has a large number of audio inputs, of which only a few are used, is unnecessarily expensive.

It is therefore now customary to construct an embedder in a modular way. Each embedder module is adapted to combine the video signal with a predetermined number of audio channels, usually four. If it is desired to combine several audio signals with the video signal, several of these embedder modules are connected to each other in series.

Figure 1 illustrates this conventional topology. That topology comprises a video converter module 10 with an input 11 for receiving a conventional composite video signal V. The video converter module 10 further comprises an analog-to-digital converter 12, a logic unit 13, and a parallel-30 to- serial converter 14. The analog-to-digital converter 12, hereinafter also referred to as ADC, converts the received composite video signal into a parallel digital video signal. The logic unit 13, hereinafter also referred to as LU, performs an operation on the parallel digital video signal if desired. The parallel-to-serial converter 14, hereinafter also referred to as PSC, appropriately converts the parallel digital video signals into a serial digital video signal. This serial digitized video signal DV is supplied at an output 19 of the video converter module 10.

The protocols for converting the analog composite video signal V to the digitized video signal DV are not important for a proper understanding of the present invention, and will not be discussed further here. It suffices to note that these can be protocols known per se, as will be clear to a person skilled in the art.

The conventional topology further comprises a number of embedder modules 20. Each embedder module 20 has a first input 21 for receiving a serial digital video signal DV, and a second input for receiving an analog audio signal AA. The digital video signal DV is supplied to a serial-to-parallel converter 23, hereinafter also referred to as SPC, and the analog audio signal is supplied to an ADC 24. The output signals of the SPC 23 and the ADC 24 are supplied to a LU 25, which combines the digital audio signal with the parallel digital video signal. The output signals of the LU 25 are applied to a PSC 26 which, similarly to the said PSC 14 of the video converter module 10, supplies a serial digital audio / video combination signal to an output 29 of the embedder module 20. .

If it is desired to combine multiple audio signals with the video signal, a plurality of embedder-30 modules 20 are coupled together in series, the first input 21 of an embedder module 20 being connected to the output 29 of the preceding embedder module. 20, as illustrated in the figure.

The above-described topology can be applied to individual audio signals. However, it is already common for conventional embedder modules to be arranged to receive and embed four individual analog audio signals. According to the current format of digital video signals, a maximum of 16 audio signals can be combined with a 1017506 3 single video signal. This means that normally a maximum of four embedder modules 20 will be placed in series with each other.

As will be apparent from the above description of Figure 1, each embedder module 20 includes an SPC, a PSC, an ADC, and an LU. This makes every embedder module still relatively complicated. Moreover, in the illustrated conventional topology, if it is desired to combine the maximum number of audio signals with a video signal, it is necessary to perform an eight-fold conversion operation on the serial digital video signal, namely four consecutive conversions from serial to parallel and back.

This large number of conversions is detrimental to the signal quality.

A further problem of the conventional topology concerns the mechanical design. It is of course possible to design each module 10, 20 as stand-alone devices, the desired inputs and outputs of which must be connected to each other by means of cables by the user.

20 However, this is very impractical. It is desirable to design the modules 10, 20 as printed circuit boards that are mounted in a common system cabinet. To this end, the printed circuit boards are placed in standard connectors mounted in the system cabinet. Conventionally for this purpose, in a system cabinet, a connector for the video converter module 10 is always associated with a group of four connectors for the maximum of four embedder modules 20. If the number of embedders used is less than the maximum number, a number of connectors must therefore be unused. remain, which means a loss of space within the system cabinet.

It is then a problem that an output of an embedder module, depending on the circumstances, must be connected to the output of the system cabinet or to the input of a subsequent embedder module. When an additional embedder module is to be placed, the existing connection must be disconnected from the output of the previous embedder module with the output from the system cabinet, and a new connection must be made from the output of the preceding 1 1 7 5 0 6 - 1 4 going enibedder module to the input of the additional embedder module.

It is of course possible to mount multiple connectors for each module in the system cabinet, and to place a module 5 only in one of those connectors, depending on the configuration. Even then, however, whenever an additional embedder module has to be placed, the previous embedder module will have to be moved to a different connector. Moreover, the number of connectors in the system cabinet is then unnecessarily large, while the large number of unused connectors means a loss of space within the system cabinet.

It is an object of the present invention to provide a solution to the above problems.

According to an important aspect of the present invention, the functions of processing the parallel digitized video signal on the one hand, and embedding of audio signals on the other hand, are performed in a single integrated video converter / audio embedder module. This integrated module has inputs for receiving digitized audio signals. Furthermore, audio converter modules are present, which convert analog audio signals into digital audio signals, and present them to corresponding inputs of the integrated video converter / audio embedder module.

According to a further important aspect of the present invention, each audio converter module is adapted to transmit the digital audio signal as supplied by a subsequent audio converter module, so that the connection of an additional audio converter module to be placed takes place with intervention. of all previous audio converter modules, without having to disconnect those previous audio converter modules.

In a system cabinet, connectors are connected to each other in a suitable manner. If only a small number of audio converter modules are used with a certain video converter / audio embedder module, the other connectors can nevertheless be used by a following group of 1017506 a video converter / audio embedder module and associated audio converter modules.

These and other aspects, features and advantages of the present invention will be further elucidated by the following description of a preferred embodiment of a system according to the invention with reference to the drawing, in which like reference numerals indicate like or similar parts, and in which: figure 1 illustrates the design of a conventional audio-in-video embedding system; Figure 2 is a figure similar to Figure 1 illustrating the design of an audio-in-video embedding system according to the present invention; Figure 3 schematically shows a perspective view of a system cabinet with modules mounted therein according to the present invention; Figure 4 schematically illustrates the connections of connectors used in the present invention; 20 and Figure 5 schematically illustrate two groups of modules mounted side by side.

Figure 2 is a figure similar to Figure 1 illustrating the topology of an audio-in-video embedding system 25 according to the present invention. This system 1 proposed by the present invention now comprises an integrated video converter / audio embedder module 30 that is similar in many respects to the previously described conventional video converter unit 10. More particularly, the integrated video converter / audio embedder module comprises 30, hereinafter also referred to as IVCAEM 30, an ADC 32 similar to the conventional ADC 12, a LU 33 similar to the conventional LU 13, and a PSC 34 similar to the conventional PSC 14. The IVCAEM 30 according to the present invention is distinguished by additional input terminals 35 which are coupled to the LU 33. These input terminals 35 are each intended for receiving a digitized audio signal.

1017506 6

In the illustrated example, the IVCAEM 30 is arranged to process four audio channels, each in fact corresponding to four individual digitized audio signals, which corresponds to the maximum number of the current formatting. The IVCAEM 30 has for this purpose four such additional input terminals 35, which are distinguished from each other by the addition of a letter; each additional input terminal 35 is thus in fact a quadruple input terminal, but this detail will not be repeated in the following. In the following, the additional input terminals 35 will also be referred to as audio input.

The system 1 according to the present invention further comprises a number of audio converter modules 40 (in this example a maximum of four per IVCAEM 30), which are distinguished from each other by the addition of a letter. Each audio converter module 40 has an input 41 and an ADC 42, similar to the ADC 24 of the conventional embedder module 20. Each audio converter module 40 has an output 49 for providing a digitized audio signal. In use, the output 49 of an audio converter module 40 is connected to an audio input 35 of the IVCAEM 30, so that the audio signal digitized by audio converter module 40 is supplied to the LU 33 of the IVCAEM 30. The LU 33 processes the digitized video signal from the ADC 32, taking into account the digitized audio signal from the ADC 42, so that a serial digital audio / video combination signal is provided directly at the output 39 of the IVCAEM 30. According to the present invention, performing additional conversion steps as is necessary in the prior art is therefore no longer necessary.

Fig. 2 shows that the output 49A of a first audio converter module 40A is connected to a first audio input 35A of the IVCAEM 30. If multiple audio signals are to be inserted, a second audio converter module 35B is used, of which the output 49B is connected to a second audio input 35B of the IVCAEM 30. In a possible embodiment of the system according to the present invention, the second audio converter module 40B is directly connected to the IVCAEM 30. In the illustrated 1 0 1 7 5 In the preferred embodiment, however, the second audio converter module 40B is connected to the IVCAEM 30 through the first audio converter module 40A. To that end, the first audio converter module 40A has a first transfer line 51A with a first transfer input 54A and a first transfer output 57A. The first transfer output 57A is connected as standard to the second audio input 35B of the IVCAEM 30. The output 49B of the second audio converter module 40B is connected to the first transfer input 54A. Thus, the output 49B of the second audio converter module 40B is connected via the first transfer line 51A of the first audio converter module 40A to the second audio input 35B of the IVCAEM 30. The IVCAEM 30 now receives the audio signals from two audio converter modules 40, and the LU 33 takes these two audio signals directly into account when processing the 15 digital video signals.

Preferably, the audio converter modules 40 are identical. It is therefore shown in Figure 2 that the second audio converter module 40B is also provided with a first transfer line 51B with a first transfer input 54B and a first transfer output 57B.

In the example shown, the system 1 is intended for connecting a maximum of four audio converter modules 40 to the IVCAEM 30. To this end, each audio converter module 40 has a second transfer line 52 with a second transfer input 55 and a second transfer output 58, as well as a third transfer transfer line 53 with a third transfer input 56 and a third transfer output 59. Of the first audio converter module 40A, the second transfer output 58A and the third transfer output 59A are connected as standard to the third audio input 35C and the fourth audio input 35D of the IVCAEM 30. When the second audio converter module 40B is connected to the first audio converter module 40A, the first and second tbansfer outputs 57B, 58B of the second audio converter module 35 are 40B '. connected as standard to the second and third transfer inputs 55A, 56A of the first audio converter module 40A, respectively. Third and fourth audio converter modules 40C, 40D (not shown in Figure 2) are similarly connected to the second and third audio converter modules 40B, 40C, respectively.

Thus, the output 49C of the third audio converter module 40C is connected via the first transfer line 51B of the second audio converter module 40B and via the second transfer line 52A of the first audio converter module 40A to the third audio input 35C of the IVCAEM 30, and is then the output 49D of the fourth audio converter module 40D via the first transfer line 51C of the third audio converter module 40C and via the second transfer line 52B of the second audio converter module 40B and the third transfer line 53A of the first audio converter module 40A connected to the fourth audio input 35D of the IVCAEM 30. The IVCAEM 30 then receives the audio signals from four audio converter modules 40, and the LU 33 takes directly into account when processing the digital video signals. these four audio signals.

It will be clear to a person skilled in the art that the principle of this system can easily be extended to several audio converter modules 40 by providing each module 40 with several transfer paths and providing the IVCAEM 30 with several audio inputs.

Thus, according to the present invention, the important advantage is offered that no additional conversion steps are required. It is important here that the audio outputs 49 of the audio converter modules 40 must be connected to the correct audio inputs 35 of the IVCAEM 30. If an audio converter module 40 were directly connected to the IVCAEM 30, the user would therefore manually select the correct audio input of the IVCAEM 30. Alternatively, multiple connectors may be available for placing audio converter modules 40, each connector being connected to a corresponding audio input 35 of the IVCAEM 30, but a drawback would then be that connectors remain unused. Because the audio converter modules 40 are provided with transfer lines as described above, the signal output and transfer outputs of a subsequent audio converter module 40 being connected to transfer inputs of a previous audio converter module 40, while furthermore the signal output and the transfer outputs of the first audio converter module 40A are connected as standard to the audio inputs 35 of the IVCAEM 30, the correct audio input of the IVCAEM 30 is automatically selected for each audio converter module 40.

It has been described in the foregoing that the successive audio converter modules 40 are connected to each other, and that the signal transfer from an audio converter module 40 to the IVCAEM 30 takes place via the intermediate audio converter modules 40. This can in principle be achieved by the physically connecting successive audio converter modules 40, but that is not preferred. Preferably, the different modules 30, 40, as already mentioned above, are placed in connectors fixedly mounted in a system cabinet.

The signal transmission described above then takes place via those connectors, for which purpose the connectors in the system cabinet are coupled to each other in a predetermined manner, as will be explained in more detail below.

Figure 3 shows a schematic perspective view of a system cabinet 100 with a plurality of receiving positions for placing a module 30 or 40. In the illustrated example, those receiving positions are defined by elongated guide brackets 110 extending from a front side 101 of the system cabinet to a rear side 102 thereof. The modules 30 and 40 are designed as or mounted on printed circuit boards 103, 104 which are provided with plate connectors 60 at their rear ends. The plate connectors 60 are in principle identical. Each plate connector has, as usual, a number of connector terminals corresponding to respective input terminals or output terminals of the relevant module, which is not shown in Figure 3. At predetermined locations in the system cabinet 100, for each pick-up position, there is a cabinet connector 120 mounted on a carrier 111 designed as a printed circuit board, corresponding to the plate connectors 60. Also the cabinet connectors 120 each have, as usual, a predetermined number connector connections. The connector connections of adjacent cabinet connectors 120 are connected to each other, as will be explained below with reference to Figure 4.

Figure 4 schematically illustrates a series of five connectors 120x to 120s mounted on the carrier 111. The number of connectors 120 will in practice be greater than five. The connectors 120i are basically identical. Each connector 120i comprises a predetermined number of N input terminals Ai (1 and an equally large number of N output terminals Bi, n, with n = 1, 2, ... N. In this example, the connectors 120 are intended for a topology with a maximum of four audio-converter modules 40 per IVCAEM 30, so that N = 4. Of successive connectors 120, the input terminals A and output terminals B are in pairs connected to each other by a fixed connection 130. More in particular, it applies that an output terminal Bi is always x of a connector 120i is connected by means of a fixed connecting line 130x to an input terminal Ai + i, x of the following connector 120i + 1, for each x from 1 to N.

Figure 4 furthermore shows that an IVCAEM 30 is mounted on a printed circuit board 103. The plate connector 60 of this printed circuit board 103 comprises N input terminals Ti to TN (N = 4), which are connected to the audio input terminal, respectively. terminals 35A to 35D of the IVCAEM 30. When the circuit board 103 is placed in a system cabinet 100 according to the present invention and the corresponding plate connector 60 connects to a cabinet connector 120i, the input terminals Tx are connected to respective output terminals Bi, x of that concerning cabinet connector 120i, for x = 1 to N.

Figure 4 furthermore shows that an audio converter module 40 is mounted on a printed circuit board 104. The plate connector 60 of this printed circuit board 104 comprises N1 input terminals Ti through TN_i (N = 4) which are connected to the transfer inputs 54 to 56 of the audio-35 converter module 40. The plate connector 60 of this printed circuit board 104 further comprises N output connections U1 to UN (N = 4), which are connected to the audio output 49 and the three transfer outputs, respectively. 57 to 59 of the audio converter module 40. When the circuit board 104 is placed in a system cabinet 1017506 11 according to the present invention and the corresponding plate connector 60 connects to a cabinet connector 120i + 1, the input terminals are Tx connected to respective output terminals Bi + i, x of those concerning cabinet connector 1201 + 1, for x = 1 to N1, and the output terminals Uy are connected to respective input terminals Ai + i, y of those concerning k st connector 120i + i, for y = 1 to N.

In the above, module 40 is mounted on a circuit board 104, and the transfer lines 51, 52, 53 form part 10 of the module 40. However, it is also possible that the transfer connections are implemented on the circuit board 104 or even directly in the connector 60, i.e. directly between the input terminals Tx and the output terminals

Uy.

15

For connecting four audio converter modules 40 in this way to the one common IVCAEM 30, use can thus be made of five identical cabinet connectors 120. However, no cabinet connector is intended solely for receiving an IVCAEM 30 or for receiving an IVCAEM 30 audio converter module 40: in principle, each case connector can be used both for receiving an IVCAEM 30 and for receiving an audio converter module 40. It is therefore possible to arrange several groups of audio modules and associated common IVCAEM in the system cabinet, whereby the groups do not have to be the same size, and wherein it is possible to utilize any existing cabinet connector.

For example, Figure 5 illustrates a situation where a first group 201 comprises two audio converter modules 40A, 40B, and thus occupies three adjacent cabinet connectors 120i, 120i + 1, 120i + 2. If a third audio converter module 40C were to be mounted on the fourth cabinet connector 120 + 3, the first group 201 would thereby be expanded to three audio converter modules, the output signal of this third audio converter module 40C being then coupled to the third audio input 35C of the IVCAEM 30 mounted in cabinet connector 201+, as explained above. The same would apply, mutatis mutandis, to a fourth audio-converter module 40D mounted on the fifth 1017506 12 cabinet connector 120i + 4. However, in the situation illustrated in Figure 5, a second IVCAEM 30 is mounted on the fourth cabinet connector 120i + 3, which is the first module of a second group 202. Since an IVCAEM 30 has no output terminals corresponding to said input terminals of the cabinet connectors , no unwanted output signal from the second IVCAEM 30 will be able to end up with the first IVCAEM 30.

In the situation illustrated in Figure 5, an audio converter module 40 is mounted on the fifth cabinet connector 120i + 4. As explained above, this would be the fourth audio converter module 40D of the first group 201 if a third audio converter module 40C were mounted on the fourth cabinet connector 120i + 3. However, now that a second IVCAEM 30 is mounted on the fourth cabinet connector 120i + 3, the audio converter module mounted on the fifth cabinet connector 120i + 4 is the first audio converter module 40A of the second group 202. The output signal of this audio module now ends up at the first audio input 35A of the second IVCAEM, and no longer at the fourth audio input 35D of the first IVCAEM.

It is noted that each module will still be provided with further connections, for example for supply voltage and, with regard to the IVCAEM, video signals. These further connections have not been discussed above, and not shown in the figures, because they do not relate to the mutual coupling of the audio signals. It will be clear that for such further connections further connectors may be present in the system cabinet. However, it is also possible that said further connectors form a whole with the discussed connectors; in that case the discussed connectors 60 and 120 thus in fact have more connections than the discussed connections.

Thus, the present invention provides an efficient system for combining audio signals and video signals. The system comprises an IVCAEM 30 with an input 31 for composite video signals and a predetermined number of N inputs 35 for digital audio signals, which IVCAEM 30 is adapted to digitize the received video signals, combined with the received audio signals, and the combined signal as to provide an output signal. The system further comprises an audio converter module 40 with an input 41 for analog audio signals and an output 49 for digitized audio signals, which audio converter module 40 further comprises N-1 transfer lines 51, 52, 53. The system further comprises a system of cabinet connectors 120 that can receive an IVCAEM 30 and an audio converter module 40, optionally. The output terminals Bj., X of each cabinet connector 120i are connected to input terminals Ai + i, x of the adjacent cabinet connector 120i + i.

It will be clear to a person skilled in the art that the scope of the present invention is not limited to the examples discussed above, but that various modifications and modifications thereof are possible without departing from the scope of the invention as defined in the appended claims. conclusions.

For example, it is possible that the modules 30, 40 are placed in the system cabinet 100 not from the front 101 but from the rear 102, and that the cabinet connectors 120 are therefore located at the front 101.

Furthermore, it is possible that an IVCAEM 30 is arranged for receiving already digitized video signals. In that case, there is a video input that is directly connected to the LU 33, and the ADC 32 can be omitted. As a variant, such an input can be present parallel to the said video input 31.

It is also possible that an audio module is arranged for receiving audio signals that have already been digitized. In that case, there is audio input that is directly connected to the audio output 49, and the ADC 42 can be omitted.

In another variant, it may be desirable to output the digitized audio / video signals in parallel format instead of serial format. In that case the PSC 34 of the IVCAEM 30 can be omitted.

1017506 14

Furthermore, it is possible that the system cabinet is arranged for allowing a plurality of audio converter modules 40 per IVCAEM 30 than the stated maximum number of N (N = 4). In anticipation of any later expansion, each cabinet connector 120 could therefore have more than N input terminals A and output terminals B, the corresponding input terminals A and output terminals B of neighboring cabinet connectors being connected to each other by more than N fixed lines 130, of which terminals there are always only N 10 in use.

1017506

Claims (11)

An integrated video converter / audio embedder module (30), comprising: a video input (31) for receiving video signals; a predetermined number of N audio inputs (35) for receiving digitized audio signals; a logic unit (33) for combining the video signals and audio signals received at said inputs (31, 35) and generating a digital audio / video combination signal; 10. an output (39) for providing the digital audio / video combination signal. 2. Module according to claim 1, further comprising an analog-to-digital converter (32) of which an input is coupled to said video input (31) of the module (30) and whose output is coupled to an input of the logical unit (33). 3. Module as claimed in claim 1 or 2, further comprising a parallel-to-serial converter (34) of which an input is coupled to an output of the logic unit (33) and whose output is coupled to said output (39) of the module (30). An audio converter module (40), comprising: an audio input (41) for receiving audio signals; an audio output (49) for providing digitized audio signals; a predetermined number of N-1 transfer lines (51, 52, 53) with respective inputs (54, 55, 56) and outputs (57, 58, 59). The module of claim 4, further comprising an analog-to-digital converter (42) of which an input is coupled to said audio input (41) of the module (40) and of which a 1017506 output is coupled to said audio output (49) of the module (40). A system cabinet (100) comprising a predetermined number of mutually substantially identical cabinet connectors (120), each cabinet connector (120j_) comprising a predetermined number of N input terminals (Ai, n) and output terminals (Bi, n), n = 1, 2, 3 ____N; and wherein from each cabinet connector (120 *) each output terminal (Bj./X) is connected by a fixed line (130x) to a corresponding input terminal (Ai + liX) of the adjacent cabinet connector (120i + i). 7. Audio-in-video embedding system (1), comprising: a system cabinet (100) according to claim 6; at least one integrated video converter / audio embedder module (30) according to any of claims 1-3; and at least one audio converter module (40) according to any of claims 4-5. 20 The system of claim 7; wherein said predetermined number (N) audio inputs (35) of the at least one integrated video converter / audio embedder module (30) is equal to said predetermined number (N1) transfer lines (51, 52, 53) of the at least one audio converter module (40) plus the number of audio outputs (49) of that audio converter module (40). The system of claim 8; Wherein said predetermined number of (N) input terminals (Ai, n) and output terminals (Bi, n) of each cabinet connector (120i) of the system cabinet (100) is at least equal to said predetermined number of (N) audio inputs (35) of the at least one integrated video converter / audio 35 embedder module (30). The system of any one of claims 7-9, wherein said integrated video converter / audio embedder module (30) is provided with a module connector (60) fitting 1017506 to the cabinet connectors (120) of said system cabinet (100); which module connector (60) is provided with input terminals (Τχ to TN), which are respectively connected to the said audio input terminals (35) of the said integrated video converter / audio embedder module (30); wherein, in the situation that said module connector (60) is coupled to a particular cabinet connector (120χ) of said system cabinet (100), said input terminals (Tx) couple to said output terminals (Βχ; Χ) of said particular cabinet connector ( 120χ), for x = 1 to N. 11. System according to any of claims 7-10, wherein said audio converter module (40) is provided with a module connector (60) fitting to the cabinet connectors (120) of said system cabinet (100); which module connector (60) is provided with input connections (Τχ to ΤΝ_χ), which are respectively connected to said transfer lines (51, 52, 53) of said audio converter module (40); Said module connector (60) further comprising a first output terminal (Ux) connected to said audio output (49) of said audio converter module (40); which module connector (60) is furthermore provided with output connections (U2 to UN), which are respectively connected to the said transfer lines (51, 52, 53) of the said audio converter module (40); wherein, in the situation that said module connector (60) is coupled to a particular cabinet connector (120χ) of said system cabinet (100), said input terminals (Tx) couple to said output terminals (Bi / X) of that particular cabinet connector ( 120χ), for x = 1 to Nl, while said output terminals (Uy) couple with the said input terminals (Αχ, γ) of that particular cabinet connector (120χ), for y = 1 to N. 1 0 1 7 5 0 6