DE20203787U1 - Test device for ISDN S. bus systems for checking the contact assignment and data activity - Google Patents

Description

Description

Test device for ISDN-S ₀ bus systems to check contact assignment and data activity

The invention relates to a test device for ISDN-S ₀ bus systems for checking the installation of the bus systems, in particular for contacts of a connection box of a bus system and the data activity via this bus system.

The ISDN testers currently known from printed publications or available on the market can essentially only check whether an ISDN connection socket has been installed correctly, i.e. whether the connections of the connection socket's contacts with the two transmit wires and the two receive wires of the ISDN-S ₀ bus have been carried out correctly.

The German generic utility model 297 08 161.6 discloses a device for testing the installation of the connection sockets of an ISDN S ₀ bus system, which is plugged into the socket of the connection socket using a plug and uses LEDs to indicate whether the connection socket is installed correctly or not. In one embodiment, so-called DUO LEDs are provided, which light up in both polarity directions, but with different colors depending on the polarity. A total of four of these DUO LEDs, visibly arranged on a surface of the housing, indicate whether the installation is correct or whether there is a wire mix-up, an interruption or a short circuit. It is also indicated when the phantom power of the NTBA (Net Terminal Block Adapter) that normally supplies the S ₀ bus fails and the emergency power of the exchange network is used instead.

An ISDN tester from DeTeWe works on the same principle, using the bipolar

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The polarity of the voltages supplied by the NTBA can be evaluated using the LEDs.

These known devices are limited to testing the installation of a connection box, i.e. checking whether the correct direct voltage is present at the contacts of the connection box. It is not possible to check the data activity on the ISDN bus. On the other hand, it is desirable to monitor the data activity, especially if a PC is connected to the ISDN bus with which Internet dial-ins are to be made. By monitoring the data activity on the ISDN bus, unwanted activities of the PC in connection with Internet dial-ins set up independently from outside or inside can be detected. This can either be a targeted, hostile intervention from outside or due to uncontrolled connection establishment by the self-installed software.

It is therefore an object of the present invention to provide a test device for ISDN-S ₀ bus systems with which, in addition to checking the installation of a connection socket, the data activity on the ISDN-S ₀ bus can also be monitored.

This object is achieved by a test device for bus systems, in particular ISDN-So bus systems, with the characterizing features of claim 1. Advantageous embodiments and developments of the test device according to the invention are specified in the subclaims.

The test device according to the invention can in principle be used for all types of bus systems in which direct voltages are supplied via certain lines to supply power to terminal devices connected to the bus system and in which data signals can also be sent and received via transmit and receive lines. The test device is therefore particularly suitable for an ISDN-So bus system in which

As is known, the so-called phantom circuit of the NTBA basic connection (Net Terminal Block Adapter) supplies the S ₀ bus with a direct voltage.

The test device according to the invention simultaneously enables the checking of the direct voltages supplied to it via the lines of the bus system and their correct contact assignment and the checking of the data activity on the transmit and receive lines of the bus system.

For this purpose, the test device according to the invention has a device-side connection device such as a plug or a socket, the contacts of which can be connected to the lines of the bus system. In the case of an ISDN-S ₀ bus system, the device-side connection device has first contacts which can be connected to the two transmit lines and second contacts which can be connected to the two receive lines of the S ₀ bus system.

The contacts of the device-side connection device are connected to one another by circuits that contain optical or acoustic signaling devices and that have a first circuit part connected to the contacts for evaluating and signaling the direct voltage occurring at the contacts and a second circuit part connected to the contacts for evaluating and signaling the changing voltage signals occurring at the contacts. The first circuit part contains first signaling devices and the second circuit part contains second signaling devices. The first signaling devices indicate the direct voltage occurring at the contacts, while the second signaling devices indicate the changing voltage signals occurring at the contacts.

The signal generators can be at least partially optical signal generators, in particular light-emitting diodes. In the embodiment to be shown, all signal generators are formed by light-emitting diodes. Here, the first signal generators

of the first circuit part are bipolar light-emitting diodes, i.e. those that light up in both directions of current flow, but with different colors depending on the polarity. However, the signal generators can also be at least partially formed by acoustic signal generators such as sine generators or the like. All signal generators can be acoustic signal generators or some of the signal generators can be optical signal generators and others can be acoustic signal generators.

In the embodiment to be shown, which relates to an ISDN-S ₀ bus system, the first circuit part is in principle constructed in a manner known per se, in that it contains a first contact loop which connects the contacts connected to the transmit lines of the bus system to one another, and in that it contains a second contact loop which connects the contacts connected to the receive lines of the bus system to one another, the circuits being arranged in such a way that current flows from one contact loop to the other during operation. In each contact loop, two bipolar light-emitting diodes (DUO LEDs) are connected in such a way that when the connection box is installed correctly, all DUO LEDs light up green.

In the case of ISDN bus systems, the second circuit part of the test device according to the invention can have a transmission path and a reception path, wherein in the transmission path the changing voltage signals between the first contacts connected to the transmission lines of the S ₀ -BuS can be displayed by means of a transmission signal generator and the voltage signals changing in the reception path between the second contacts connected to the reception lines of the S ₀ -BuS can be displayed by means of a reception signal generator.

In the transmit and receive paths, there may be a differential amplifier, the inputs of which are connected to the first contacts and the second contacts of the connection device, respectively, and the outputs of which are connected to

the transmitting or receiving signal generator. The connecting lines between the contacts and the inputs of the differential amplifiers can contain capacitors so that only the changing voltage signals are transmitted via these connecting lines.

The supply voltage for the differential amplifiers can advantageously be supplied from the first circuit part, with the first circuit part receiving the voltage via the contacts connected to the live lines of the bus system. As will be seen from the exemplary embodiment, a first supply voltage input of the two differential amplifiers can be connected to a common ground of the device and the contact loops can each be connected to a second supply voltage input of the two differential amplifiers via a diode connected in the forward direction. Furthermore, the common ground can each be connected to the contact loops via a diode connected in the forward direction. In this way it is ensured that the two differential amplifiers are always supplied with a supply voltage that is directed in the same way, even if the polarity of the DC voltages supplied to the contact loops via the lines of the bus system is reversed. The light-emitting diodes and series resistors contained in the first circuit part act as voltage dividers and thus ensure that only a portion of the DC voltage supplied by the contact loops is applied to the differential amplifiers.

0 The connection device of the test device can be provided by one or more plugs or sockets, which can be provided by RJ45 plugs and/or RJ45 sockets. Two sockets, in particular two RJ45 sockets, can also be arranged on the test device, so that the test device can advantageously be looped into a line.

In the following, an embodiment of the test device according to the invention is described in more detail with reference to the drawing figures.

Show it:

Fig. 1 is a photographic representation of an embodiment of a test device according to the invention;

Fig. 2 shows an embodiment of a circuit arrangement of a test device according to the invention.

Fig. 1 shows an embodiment of a test device according to the invention for ISDN-S ₀ bus systems, which has an input socket arranged in the upper front face as a connection device, into which a connecting cable can be plugged, which is connected, for example, to a connection box of the bus system. The test device has a total of 6 LEDs on its upper side, of which the four LEDs labeled al, a2, bl, b2 signal the correct contact assignment and polarity of the contacts connected to the transmit lines and receive lines of the bus system. These are DUO LEDs that light up in both current flow directions, but with different colors (green or red) depending on the polarity. The other LEDs labeled Rx and Tx are unipolar LEDs and signal the data activity of the S ₀ bus, with the Tx diode indicating the sending of data on the transmit lines of the S ₀ bus, while the Rx diode indicates the receiving of data on the receive lines of the So bus. The designations of the DUO LEDs al and bl on the test device according to Fig. 1 correspond to the reference symbols D2 and D3 in the circuit diagram of Fig. 2 and the designations a2 and b2 on the test device correspond to the reference symbols Dl and D4 in the circuit diagram of Fig. 2. It is symbolically indicated on the test device that the DUO LED ¹ s are contained in a contact loop connecting contacts 4 (K4) and 5 (K5).

and that the DUO-LEDs a2 and b2 are contained in a contact loop containing the contacts 3 (K3) and 6 (K6).

According to the circuit diagram of Fig. 2, the present embodiment of the test device according to the invention has two connection devices J1 and J2, which can be provided by plugs such as RJ45 plugs or sockets such as RJ45 sockets. In the connection devices, the contacts K3 to K6 are occupied and connected to one another by a circuit to be described. These contacts are arranged in the connection devices in such a way that they can be connected to the correspondingly numbered transmission lines 3 and 6 and reception lines 4 and 5 of an ISDN-S ₀ bus system.

The circuit diagram in Fig. 2 has a first circuit section, visible in the right half of the picture, in which the direct voltage occurring at the contacts K3 to K6 is evaluated and indicated accordingly by the DUO LED ¹ s Dl to D4. Each of the two contact loops K3/K6 and K4/K5 contains two DUO LEDs. The 4 DUO LEDs Dl to D4, together with the matching resistors Rl to R4, load the phantom feed of the BUS supply voltage symmetrically. The DUO LEDs indicate whether the supply voltage is present on the NTBA, whether there are line faults and whether the feed is running in normal operation or emergency operation.

The current flows from one contact loop to the other, whereby the direction of the current depends on the polarity of the phantom power supply. In this respect, the circuit itself is known from the state of the art mentioned at the beginning. However, the test device according to the invention now goes beyond the state of the art in that a consumer contained in a second circuit part (see left half of the figure) is connected to the current path between the contact loops. This consumer is controlled by 2 differential amplifiers IClA

and IClB. The second circuit part evaluates and displays the data activity, i.e. the sending or receiving activity on the S ₀ bus.

Diodes D7 to D10 ensure that the same supply voltage is always fed to the differential amplifiers IClA and IClB, regardless of the polarity of the phantom feed. For reasons of clarity, the supply voltage is only shown for the IClB component, but is applied to the IClA component in the same way. During operation, the same potential is always present at point 8 of the circuit due to the effect of diodes D7 to D10. If the contact loop K3/K6 is at a positive potential due to the polarity of the phantom feed, the current flows through diode D8 via the differential amplifiers IClA and IClB to ground (GND) and from there through diode D9 into the contact loop K4/K5. Conversely, if the contact loop K4/K5 is at a positive potential due to the polarity of the phantom power supply, the current flows from there via the diode D10 through the differential amplifiers IClA and IClB to ground (GND) and from there through the diode D7 to the contact loop K3/K6. The former case concerns the normal case in which the NTBA is in mains power mode, while the latter case describes the emergency operation in which the NTBA is powered by the exchange. Depending on the polarity, the DUO LEDs D1 to D4 then light up uniformly green or red.

With the usual polarity of the NTBA (transmitting lines at -40 V, receiving lines at 0 V), the light-emitting diodes in the first circuit part and their series resistors Rl - R4, whose resistance values are in the order of 4 kΩ, cause supply voltages of 10 - 15 V, in particular approx. 12 V, to be applied to the differential amplifiers IClA, IClB.

The second circuit part is fed with the changing voltage signals occurring at contacts K3 to K6. For this purpose, capacitors C1 to C4 are contained in the corresponding supply lines so that only the voltage changes are transmitted. The inputs of the differential amplifier IClB are connected to contacts K3 and K6 in such a way that when data is transmitted on the transmit lines of the S ₀ -BuS, a voltage difference signal is fed to the IClB module and amplified by it, causing the transmit diode D6 to light up. The IClA module is connected to contacts K4 and K5 in the same way so that corresponding receive activity on the S ₀ -BuS is displayed in the receive diode D5.

Furthermore, additional connecting lines are provided which contain the resistors R7 and R11 or R12 and R14. These connecting lines serve as voltage dividers for the signal voltage which is coupled out via the capacitors C1 and C4 or C2 and C3 and amplified by the differential amplifiers IClA and IClB and displayed by the diodes D5 and D6 .

In the example, resistors R1 to R15 have resistance values of 4 kΩ, while resistor R16 has a resistance value of 220 Ω. With these values, the total current load of the test device is approximately 8 mA, which is far below that of a terminal device. Nevertheless, in order to prevent data corruption due to a possible asymmetrical load on the NTBA's phantom transformer, the supply voltage for the evaluation electronics in the form of the ICIA and ICIB modules must be taken symmetrically. Due to the relatively low current load, the test device can also remain permanently connected to the ISDN-S ₀ bus if desired.

The flexibility of the test device according to the invention is achieved, among other things, by the fact that it can be connected to the two RJ45 sockets

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can currently be looped into a line if there are no more free sockets. This eliminates the need to install another connection socket. To easily connect to the ISDN bus, the test device according to the invention is simply plugged into any ISDN connection socket using the short connection cable provided. This means that all data traffic on the bus can then be monitored.

Claims (14)

1. Test device for bus systems, especially ISDN-S ₀ bus systems, with - a device-side connection device (J1, J2), whose contacts (K3-K6) can be connected to the lines of the bus system, - circuits through which the contacts (K3-K6) are connected to each other and in which optical or acoustic signaling devices (D1-D6) are contained, characterized in that - the circuits have: - a first circuit part connected to the contacts (K3, K6) for evaluating and signalling the direct voltage occurring at the contacts (K3-K6), in which first signal generators (D1-D4) are contained, and - a second circuit part connected to the contacts (K3-K6) for evaluating and signaling the changing voltage signals occurring at the contacts (K3-K6), in which second signal generators (D5, D6) are included. 2. Test device according to claim 1 for ISDN-S ₀ bus systems, characterized in that from the device-side connection device (J1, J2) first contacts (K3, KG) can be connected to the 2 transmission lines and second contacts (K4, K5) to the 2 reception lines of the So bus system. 3. Test device according to claim 1 or 2, characterized in that the signal generators (D1-D6) are at least partially optical signal generators, in particular light-emitting diodes (D1-D6). 4. Test device according to claim 1 or 2, characterized in that
the signaling devices (D1-D5) are at least partly acoustic signaling devices. 5. Test device according to one of claims 2 to 4, characterized in that - the first circuit part contains a first contact loop which connects the first contacts (K3, K6) to one another, and that it further contains a second contact loop which connects the second contacts (K4, K5) to one another, and - the circuits are arranged in such a way that current flows from one contact loop to the other during operation. 6. Test device according to claim 5, characterized in that each contact loop contains at least one signal generator (D1-D4). 7. Test device according to claim 6, characterized in that each contact loop contains two signal generators (D1-D4), in particular light-emitting diodes, in particular bipolar light-emitting diodes. 8. Test device according to one or more of claims 2 to 7, characterized in that - the second circuit part has a transmit path and a receive path, and - in the transmission path, the changing voltage signals between the first contacts (K3, K6) can be displayed by means of a transmission signal generator (D5), and - in the receiving path, the changing voltage signals between the second contacts (K4, K5) can be displayed by means of a receiving signal generator (D6). 9. Test device according to claim 8, characterized in that a differential amplifier (IC1A, IC1B) is present in each of the transmit and receive paths, the inputs of which are respectively connected to the first contacts (K3, K6) and the second contacts (K4, K5) and the outputs of which are connected to the transmit (D5) and the receive signal generator (D6). 10. Test device according to claim 9, characterized in that capacitors (C1, C4) are connected in the connecting lines of the contacts (K3, K6; K4, K5) with the inputs of the differential amplifiers (IC1A, IC1B), so that only the changing voltage signals are transmitted. 11. Test device according to claim 9 or 10, characterized in that the supply voltage for the differential amplifiers (IC1A, IC1B) is supplied by the first circuit part. 12. Test device according to claim 11, characterized in that a first supply voltage input (point 4 ) of the differential amplifiers (IC1A, IC1B) is connected to a common ground (GND) and the contact loops are each connected to a second supply voltage input (point 8 ) of the differential amplifiers (IC1A, IC1B) via a diode (D9, D10) connected in the forward direction, 13. Test device according to claim 12, characterized in that the common ground (GND) is connected to the contact loops via a diode (D7, D8) connected in the forward direction. 14. Test device according to one or more of the preceding claims, characterized in that the device has two connection devices (J1, J2) such that it can be looped into a line.