DE102009031569A1 - Educational network for e.g. computer-assisted training, has work stations connected with each other, where stations and switching unit are connected with each other and picture transmission takes place between stations by switching unit - Google Patents

Abstract

The network has computer work stations (6, 7) connected with each other, and a computer provided with a keyboard, a mouse, a monitor and a switching unit (8). A picture transmission takes place between the work stations by the switching unit without performing digital signal processing and transformation in the signal type. The switching unit and the work stations are connected with each other by a cable (9). The switching unit exhibits a switching circuit for digital processing of transmitted signals and transformation into picture signals.

Description

The Invention relates to an educational network, as is for the computer-aided Training and the computer-aided Lessons needed becomes.

such Networks consist of interconnected computer workstations, where Each workstation has a switching unit installed between it the monitor output of the computer and the input of the monitor is. The switching units of the individual workstations are interconnected via system cables networked and can thereby exchange signals with each other. By means of a control keyboard becomes a switching unit as a transmitter and other switching units switched as a receiver. With such an arrangement of the network, the image signals of a Computers are displayed on the monitor of one or more other workstations become. At each computer work station, image signals are converted into transmission signals or reversed transmission signals converted into image signals.

A typical prior art educational network shows 1 , The network consists in this example of a total of 12 computer workstations. At each workplace, a switching unit is arranged as an electronic circuit between the computer and the monitor, which has a switch and an interface to the image information of other computers can rest and another interface with the image information (image signals) sent to the computers of other workstations can be.

Regarding The image signals are distinguished between analog and digital systems. Switching units for transmission amplify analog signals these signals and transmit she to the other switching units.

In the known digital systems, the signals are transmitted as follows:
The image information digitally encoded by the computer (image signals) is received by the switching unit and forwarded to the monitor. At the same time, the image signals are converted into transmission signals and transmitted to other switching units. Each of these switching units digitally processes the transmission signals, evaluates them and converts them into image signals. These image signals are then sent to the monitor. The quality of the image transmission depends on the bit error rate. It indicates how often a bit within the bit sequence is transmitted incorrectly. If the bit error rate is low, the received image can be reconstructed without error by digital processing. The bit error rate, in turn, depends on the bit-energy-to-noise power density ratio. The bit energy depends on the geometric resolution and the color depth of the image as well as the refresh rate; the noise power density depends on the type of signal and the length of the transmission link, which can be up to 40 m for interference-free reception with a digital electrical signal and several 100 m in the case of an optical signal. In a pedagogical network, the length of cables for transmission between workstations may vary widely according to local circumstances. By taking place in each switching unit digital signal conditioning and the conversion of the transmission signals in image signals and the conversion of the image signals in transmission signals ensures that the Bitenergie-noise power density ratio is well above the critical value below which the monitor no longer represents the image, and the bit error rate is low.

On Reason for digital processing in each switching unit the signals and their reconstruction is given the large amounts of data Of image signals a very high circuit complexity required. The conversion of the image signals into transmission signals is generated in each switching unit additional Effort. Inevitably This effort is associated with high costs.

Known are also educational networks for image transmission, where for several computer workstations a switching unit is used.

A Switching unit for several computer workstations has the disadvantage that a certain number of computers, in the Usually two computers have to stand next to each other. At stand-alone Computers do not reduce the effort. On the contrary, he is even bigger, there the connections for the other computer will not be used.

task The invention is therefore an educational network for a flawless image transfer with a lower circuit complexity and consequently to provide lower costs.

According to the invention Task by an educational Network of interconnected jobs, each consisting of a computer with a keyboard and mouse, a monitor and a switching unit, solved, being an image transfer between jobs by a switching unit without a digital signal processing and conversion into another signal type and by means of a cable the switching units and thus the workplaces are interconnected.

According to a particularly preferred embodiment of the invention, the network exists From workplaces each with a switching unit without digital signal conditioning and conversion into another type of signal and from workplaces each with a switching unit having a circuit for digital processing of transmission signals and conversion to image signals and work stations each with a switching unit having a circuit for converting the Picture signals in transmission signals and the latter switching units are connected to each other by means of a cable.

To a further preferred embodiment the network according to the invention are the jobs with switching units without digital signal conditioning and conversion into another signal type in series with the workstation with one Switching unit for digital processing of the transmission signals and their Conversion into image signals and the workstation with a switching unit for converting the image signals into transmission signals connected.

at a further embodiment According to the invention, the network consists of several series connected Groups of jobs, with jobs in each group with a switching unit without digital signal conditioning and conversion into another signal type with the workstation with the switching unit for digital processing of the transmission signals and their conversion into image signals and the workstation with the switching unit for converting the image signals into transmission signals are switched and the groups are interconnected by means of a cable are connected.

A another embodiment The invention provides that the number of jobs with interconnected switching units without digital signal conditioning and conversion to another signal type is equal to or greater as the number of jobs with digital signal processing and conversion into another signal type.

A another embodiment The invention provides that the workstations connected in series with a switching unit without digital signal conditioning and conversion in another signal type, a switching unit with circuits for digital processing of the transmission signals and their conversion into image signals and to the conversion of the image signals in transmission signals is assigned and these switching units with the groups thus formed jobs connected by a cable.

The inventive educational Network has the advantage that it is one compared to the state of the art requires less circuit complexity and therefore more cost-effective can be produced. For transmission digitally encoded image information between computer workstations various switching units used. Mostly switching units are without used a digital signal conditioning and conversion. Only if the bit-energy-to-noise ratio threatens to be critical Fall below the limit and thus there is a risk that the monitor no longer displays the image and if it is one longer Route for the transmission signals Switching units come with digital signal processing and conversion into another signal type used.

in the Below, the invention will be explained in more detail with reference to block diagrams. Show it:

1 : a prior art educational network

2 A network according to the invention without digital signal conditioning and conversion

3 , an embodiment of the network according to the invention with digital signal processing and conversion

4 A further embodiment of the invention, consisting of several groups, in which a plurality of workstations without digital signal conditioning and conversion are connected to a switching unit with digital signal processing and conversion in a different signal type.

2 shows an educational network with 12 same computer workstations 6 . 7 in series by means of cables 9 are switched. Between each monitor marked as a display and each PC with keyboard is the switching unit 8th with the switch 2 arranged. The MAX 3845 circuit from Maxim is used as a changeover switch. For image transmission this network only shows the switching units 8th on, which provide neither a digital signal processing nor a conversion to another signal type. The switching unit 8th of the workplace 6 receives the image signals from the PC. The switch 2 sends these image signals to the display of this workstation and to the next in-line switching unit 8th the following workplace 7 , The switching unit 8th with the switch 2 second job 7 receives the image signals from the switching unit 8th of the workplace 6 and forwards them to the workstation display 7 and to the switching unit 8th the following workplace. This process continues up to the switching unit 8th the last job.

It has been found that with normal image resolutions up to 1280 × 1024 pixels a conversion of the image signals into transmission signals and a digital processing of the transmission signals and their conversion into image signals are not required. The length of the cables 9 between two switching units 8th should not exceed approx. 15 m. The total length of the cables 9 between the switching units 8th should not exceed about 40 m. As a cable 9 In this embodiment, a DVI cable is used. Every job 6 . 7 can also be used as a lecturer's workstation with a special keyboard.

How out 3 As can be seen, this network also consists of 12 computer workstations, of which only a few workstations are included for the sake of clarity 10 . 11 . 12 . 13 and 14 are numbered. Six similar jobs 11 and 12 each have the switching units 15 without digital signal processing and conversion into another signal type. Three similar jobs 10 . 14 each with a switching unit 16 have a circuit 1 for digital processing of the received transmission signals and their conversion into image signals and three similar workstations 13 , each with a switching unit 17 , have the circuit 3 for converting the image signals into transmission signals. As a circuit 1 The circuits SIL 1160 and INDR311 of the companies Silicon Image and inova Semiconductors are used in the mentioned exemplary embodiments. As a circuit 3 The circuits SIL 1161 and INDT 331 are also used by these companies.

The switching units 15 . 16 and 17 are by means of the VDI cable 9 and the switching units 17 with the successive switching unit 16 by means of the cable 19 connected together, being as a cable 19 a Kat7 cable is used in this example.

To describe the function of this network, it is assumed that the image from the PC of the workstation 10 on all displays of the following workstations 11 . 12 . 13 and 14 to be shown until the last job. The switching unit receives this 16 of the workplace 10 the image signals from the PC. The switch 2 Forwards these image signals to the display of the workstation 10 and to the switching unit 15 the next workstation connected in series 11 , The switch 2 the second switching unit 15 receives the image signals from the switching unit 16 the first job 10 and directs them to the display and to the switching unit 15 the third job 12 , The switch 2 the switching unit 15 of the workplace 12 directs the from the switching unit 15 of the workplace 11 received image signals to the display and to the switching unit 17 of the workplace 13 , The switch 2 the switching unit 17 directs the received image signals to the display and the circuit 3 which converts the image signals into transmission signals and these to the switching unit 16 of the workplace 14 forwards. The circuit 1 the switching unit 16 of the workplace 14 prepares the received transmission signals digitally and converts them into image signals. The switch 2 the switching unit 16 of the workplace 14 directs the image signals to the display and the switching unit 15 the next workplace. This process continues until the switching unit 17 the last workstation received the signal.

In this particularly preferred embodiment of the invention, at high image resolutions, for example, 1900 × 1200 pixels become the switching units 16 with digital signal conditioning and conversion then used before the bit-power-to-noise power density ratio falls below the critical limit, and the distances 9 for signal transmission to longer distances.

The length of the cables 19 between the switching units 17 and 16 , which exchange electrical transmission signals, should not exceed about 40 m. For optical transmission signals, the length of the cables 19 several hundred meters. The total cable length between all switching units can then be arbitrarily large.

4 shows a network according to the invention of twelve similar computer workstations 18 , The network consists of three groups of four workstations each 18 , in turn, each of the switching units 8th without digital signal processing. The signal transmission between the workstations 18 takes place analogously to the signal transmission according to 2 , Each of the groups is connected to a switching unit 5 connected according to the prior art. The circuit 3 each switching unit 5 converts the image signals into transmission signals and conducts them via the cable 19 to the circuit 1 the next switching unit 5 which digitally processes the received transmission signals and converts them into image signals. This process continues until the transmission signal is the last switching unit 5 has reached.

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circuit

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switch

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switching unit

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switching unit

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electric wire

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switching unit

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switching unit

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electric wire

Claims (6)

Educational network of interconnected workplaces consisting of a computer with keyboard and mouse, a monitor and a switching unit, characterized in that an image transmission between the workstations ( 6 ; 7 ) by means of the switching unit ( 8th ) without a digital signal conditioning and conversion into another type of signal and by means of a cable ( 9 ) the switching units ( 8th ) and thus the jobs ( 6 ; 7 ) are interconnected. Educational network according to claim 1, characterized in that the network of workplaces ( 11 ; 12 ) each with the switching unit ( 15 ) without digital signal processing and conversion into another signal type as well as from the workstations ( 10 ; 14 ;) each with the switching unit ( 16 ), which is a circuit ( 1 ) for digital processing of transmission signals and conversion into image signals and the workstations ( 13 ) each with the switching unit ( 17 ), which is a circuit ( 3 ) for converting the image signals into transmission signals and the switching unit ( 17 ) by means of the cable ( 19 ) with the switching unit ( 16 ) connected is. Educational network according to claim 1, characterized in that the workstations ( 11 ; 12 ) with the switching units ( 15 ) without digital signal conditioning and conversion into another type of signal in series with the workstation ( 10 ) with a switching unit ( 16 ) for the digital processing of the transmission signal and its conversion into an image signal and the workstation ( 13 ) with the switching unit ( 17 ) are connected to the conversion of the image signal in the transmission signal. Educational network according to claim 2 or 3, characterized in that it consists of several series-connected groups of workplaces ( 10 ; 11 ; 12 ; 13 ), where in each group the jobs ( 11 ; 12 ) with switching units without digital signal conditioning and conversion to another type of signal in series with the workstation ( 10 ) with the switching unit ( 16 ) and the workplace ( 13 ) with the switching unit ( 17 ) and the groups are interconnected by means of the cable ( 19 ) are connected. Educational network according to one of Claims 2 to 4, characterized in that the number of workstations ( 11 ; 12 ) with the switching units ( 15 ) is equal to or greater than the number of workstations without digital signal conditioning and conversion to another signal type ( 10 ) with the switching unit ( 16 ) for digital signal processing and conversion into another signal type or equal to or greater than the number of workstations ( 13 ) with the switching unit ( 17 ) for converting the image signals into transmission signals. Educational network according to claim 1, characterized in that the workstations connected in series ( 18 ) with the switching unit ( 8th ) without digital signal processing and conversion into another signal type, the switching unit ( 5 ) with the circuits ( 1 ; 3 ) is assigned to the digital signal conditioning and conversion in another signal type and the switching units ( 5 ) with the groups of jobs ( 18 ) by means of the cable ( 19 ) are interconnected.