SE470470B - Closing arrangement at an interface at one end of a coupler and disconnectable conductor cable - Google Patents

Description

'ÉfÜ i 10 15 20 25 30 35 ñ.-_ U g] "-'rx"! Fi "* å' 2 with termination resistor must be manually pushed into the base or pulled out of the base.

These solutions have the disadvantage that the termination means is a separate unit which must be handled separately.

According to another prior art, described in US-4, 988, 890, a plurality of units are connected by running the multi-conductor cable or SCSI bus in a circular connection, or loop, from one first unit to the others and back to the first unit. again. Both termination means are arranged in the first unit. This has the obvious disadvantage that two expensive multi-conductor cables thus have to be connected to the first unit and to the other units. A variant of the solution with circular coupling is described in US-5, 099, 137.

The solutions according to the prior art thus require extra work by an operator who wants to connect different external SCSI devices, and extra amount of cable that must be connected and installed.

Objects of the present invention The main object of the present invention is to simplify and automate the connection of external devices via SCSI interfaces.

Another object of the present invention is to provide automatic disconnection and connection of termination means for a first SCSI unit in a first computer unit depending on whether an external SCSI unit is connected to or disconnected from the first computer unit.

The main object is achieved with an arrangement of the type specified in the characterizing part of claim 1. Further features and further developments of the arrangement according to the invention are stated in the other claims. Brief Description of the Drawings In order that the present invention may be readily understood and practiced, it will be described by way of illustration and with reference to the accompanying drawings, in which: Figure 1 shows a schematic view of an embodiment of a device according to the invention.

Figure 2 shows a block diagram of an arrangement according to the present invention.

Fig. 3 shows connection of multi-connector parts and interconnection of computer units according to an embodiment of the present invention.

Figure 4 shows an embodiment of a device according to the invention.

DETAILED DESCRIPTION OF THE INVENTION The invention is described here with reference to Fig. 1. According to one embodiment, the arrangement according to the invention comprises a first multi-connector part 10. The first multi-connector part 10 comprises first contact parts 20, which are individually connected to conductor 30 in a first multi-conductor cable 40. Some of the conductors, or all of the conductors, in the multiconductor cable 40 may be a data bus, such as a SCSI bus.

The first multi-connector part 10 also comprises at least a first control signal contact part 50, which via a conductor 55 is connected to a switch means 60 comprising a control element 61, which controls a number of normally closed switch elements 62. A switch element 62 may for instance be of some kind semiconductor valve. Depending on the signal level at the control signal contact part 50, the switching means 60 switches in or out of termination means 70, also called terminator means. The signal level at the control signal contact portion 50 is preferably a voltage level, but may alternatively be, for example, a current level. Each terminator means 70 is connected via a switch element 62 controlled by the switching means 60 to each of the first contact parts 20 in the first multi-contact device part 10, and thus also to the conductors 30 in the first It is also within the scope of the invention that the multi-conductor cable 40 comprises one or more conductors which are not connected to any terminator means 70.

The multi-conductor cable 40 may, for example, comprise one or a pair of conductors for power supply or earth conductors, which conductors do not need to be connected to terminator means, as is known to the person skilled in the art.

The terminator means 70 may comprise one or more resistors and / or other passive circuit elements. The terminator means 70 may alternatively comprise active circuit elements, such as integrated circuits, possibly in combination with passive circuit elements.

The first multi-conductor cable 40 is shown in Fig. 1 with only two conductors to simplify the description, but in reality the number of conductors can of course be higher. The cable 40 may, for example, comprise 18 conductors and the first connector may comprise 18 first contact parts 20 and a first control signal contact part 50, which provides control to the control element 61 to control all switch elements 62 in unison, or several first control signal contact parts 50, which provide control to several control elements. 61 to control each group of switch elements 62.

The arrangement further comprises a second multi-connector part 80 which is connectable to the first multi-connector part 10.

When the second multi-connector part 80 is not connected to the first connector part 10, no control signal is received from the control signal contact part / parts 50 to the control element 61 to control the switch elements 62. Then the switching means 60 keeps the connection closed between each conductor 30 in the cable 40 and the respective terminator means 70. At the end of the multi-conductor cable 40 of the signal 47n: PH »5, the conductors 30 are thus terminated so that signal reflexes or other problems do not occur.

The other end 75 of the multi-conductor cable 40 may also be terminated by some kind of additional termination means or terminator means. The other end 75 may also be connected to a device, such as a processor or personal computer. The multi-conductor cable 40 can thus be terminated at both ends, ie partly by the terminator means 70 at one end and partly by the further terminator means at the other end.

In order to cause the switching means 60 to keep the switch elements 62 closed, when the second multi-connector part 80 is not connected to the first connector part 10, a high signal level is arranged on the conductor 55, for example by a so-called "pull-up" resistor 90. The resistor 90 is connected between a first voltage level U1 and the conductor 55, thereby causing the signal level on the conductor 55 to go high when the first control signal portion 50 is not connected to any other contact portion having a different signal level. When the signal level on the conductor 55 is high, the switching means 60 maintains its switch elements 62 in the closed state, which connects the conductors 30 to the terminator means 70.

When the second multi-connector part 80 is connected to the first connector part 10, the first control signal part 50 is connected to a second control signal part 100 in the second multi-connector part 80. The second control signal part 100 can, for example via a conductor 110 in a multi-conductor cable 120, be connected to a second voltage level UO (Fig. 1, Fig. 2). The second voltage level UO can, for example, be a low voltage level such as signal ground. Thus, when the second multi-connector part 80 is connected to the first multi-connector part 10, the signal level on the conductor 55 is caused to correspond to the signal level UO, and the switching means 60 then changes state to keep its switch elements 62 in a broken state. Thus, the terminator means 70 is disconnected from the conductors 30 of the multi-conductor cable 40. The arrangement according to the invention thus means that a sensing means causes the terminator means 70 to be disconnected from the signal conductors 30, at the same time as other contact parts 130 of the second multi-connector part. 80 is connected to the first contact portions 20 of the first multi-connector portion 10.

The other contact parts 130 are individually connected to conductors 140 included in the multi-conductor or signal cable 120.

The first multi-connector portion 10, the first cable 40 or the first bus 40, the terminator means 70 and the switching means 60 are included in a first computer unit 150. The multi-conductor cable 120 is preferably an external SCSI bus which connects the first computer unit 150 to a second computer unit 160.

Referring to Fig. 2, it is shown how the first computer unit 150 can be connected to the second computer unit 160 and to a third computer unit 170.

The first multi-connector portion 10 of the first computer unit 150 may be connected to a third multi-connector portion 180 via the second multi-connector portion 80 and the multi-conductor cable 120. According to one embodiment, the third multi-connector portion 180 connects the conductor 110 in the multi-conductor cable 120 to the signal level Uo via a fourth multi-connector part 200 in the second computer unit 160. The signal level Uo is provided according to this embodiment from the second computer unit 160.

According to another embodiment, the second voltage level Uo is supplied to the first control signal portion from a source within the first computer unit, as shown in Fig. 3. According to the embodiment shown in Fig. 3, the first computer unit 150B comprises a first multi-connector portion 10B. The first multi-connector part 10B comprises, like the previous first contact parts 20B and a first control signal contact part 50B, but it comprises the described multi-connector part 10, in addition a third control signal contact part 202 which is connected to the second signal level Uo within the first computer unit 10. . when a second multi-connector portion 80B is connected to the first multi-connector portion 10B, the first control signal contact portion 50B is connected to the third control signal contact portion 202, via corresponding contact portions 204 and 100B, respectively, of the multi-connector portion 80B. The connectors 204 and 100B may be directly connected to each other via a conductor 206 in the multi-connector portion 80B, as shown in Fig. 3. Alternatively, the multi-connector portion 80B is not provided with a conductor 206, and the two connectors 204 and 100B may then be connected to each other via conductors. 208 and 10B, respectively, which are included in a multiconductor cable 120B and which are connected to each other at or within the second computer unit 16OB at the opposite end of the multiconductor cable 120B. Both conductors 110B and 208 may further be connected to the signal level Uo also in the second computer unit 16OB, as shown in Fig. 3. The multi-conductor cable 120B may otherwise correspond to the multi-conductor cable 120 described above and below.

Referring to Fig. 2, the signal conductors 140 in the multiconductor cable 120 are connected via the multi-connector portion 180 and the multi-connector portion 200 to a unit 220 in the second computer unit 160. The unit 220 may include a SCSI controller, and other data processing equipment included in the second computer unit. 160.

According to another embodiment of the invention, the multiconductor cable 120 is fixedly connected to the second computer unit 160, instead of using third and fourth multi-connector components 180 and 200.

Within the second computer unit 160, the bus conductors 140 may be connected to bus conductors 30 '. The second computer unit 160 may comprise terminator means 70 'corresponding to the terminator means 70 of the first computer unit 150. Furthermore, the computer unit 160 may comprise a switching means 60' and a multi-connector part 10 'corresponding to the switching means 60 and the multi-connector part 10 of the first computer unit 150. 10 15 20 25 30 35 "il If" '* 8 This means that additional computer units can be daisy-chained to the computer units 150 and 160, with automatic connection and disconnection of the internal terminator means 70 and 70', respectively. .

Fig. 2 shows an example where two computer units 160 and 170 are chained to the first computer unit 150.

In the arrangement according to Fig. 2, the third computer unit 170 is connected to the second computer unit 160 via a multi-conductor cable 120 ', which corresponds to the multi-conductor cable 120 between the computer units 150 and 160.

With respect to connection and interface to other units, the third computer unit 170 may correspond to the second computer unit 160. Thus, the third computer unit 170 comprises bus conductors 30 ", the unit 160, respective means 70" and 60 "and a multi-corresponding bus conductors 30 ' in computer connector part 10 "corresponding to the means 70 ', 60' and 10 'described above. The unit 220 'in the third computer unit 170 may correspond to the unit 220 in the second computer unit 160, but the data processing equipment may be of different types, as will be appreciated in further discussion of peripherals below.

Since the third computer unit 170 is connected to the second computer unit 160, the switching means 60 'of the second computer unit 160 is in its broken state. The terminator means 70 'are thus not connected to the bus conductors 30'.

On the other hand, no further computer unit is connected to the multi-connector part 10 "of the third computer unit in the arrangement according to Fig. 2. This means that the terminator means 70" are connected to the bus conductors 30 "in the manner described above with reference to Fig. 1, and bus which u). consists of the signal conductors 30 "is thus terminated by means of the terminator means 70". Thus, the SCSI bus can be terminated partly at the end 75 (Fig. 1) of the composite bus by means of the further terminator means, as mentioned above, and 10 15 20 25 30 35 1473 476 'r "! I" "9 partly by the terminator means 70" at the opposite end of the composite SCSI bus.

The arrangement according to the invention thus means that a number of n computer units can be chain-connected with ease, and the internal terminator means are automatically connected in the computer unit where bus termination is needed, while the terminator means are automatically disconnected in the computer units where they are not needed.

The arrangement according to the invention thus relates to interfaces, preferably Small Computer Systems Interface (SCSI), for connecting one or more peripherals, or peripheral units, to a computer. The computer can, for example, consist of a personal computer, and the peripheral equipment can, for example, consist of disk memory units, tape memory units or CD-ROM reader units.

According to an application of the arrangement according to the invention, the first computer unit 150 is constituted by a personal computer with external SCSI interface and the second computer unit 160 by a disk memory unit, while the third computer unit 170 is constituted by a tape memory unit. An operator occasionally wishes to connect the tape memory unit 170 to the disk memory unit 160 to back up the contents of the disk memory unit.

In the case that prior art interfaces and buses are used, this means that the operator must manually open the housing within which the terminator means are arranged and disconnect the terminator means at the disk memory unit when the tape memory unit 170 is connected to the disk memory unit 160. When the operator then wants to disconnect the tape memory unit again 170 from the disk memory unit 160, the housing must be reopened and the terminator means manually reconnected. If the known technology with circuit connection is used, it means a problem that the operator must break the loop and arrange with at least two multi-conductor cables. »_ 10 15 20 25 30 35 a 'I fi'7 ñ L! När fï fi- Lä: U _ 10 On the other hand, when the arrangement according to the invention is used, the operator does not have to worry at all about the terminator means. When the operator connects the tape memory unit 170 to a disk memory unit 160 with an interface arrangement according to the present invention, the internal bus terminator means 70 'are automatically disconnected. Only a multi-conductor cable f? needed, namely the multi-conductor cable 120 '.

Referring to Figure 4, an embodiment of a computer unit 222 in accordance with the arrangement of the invention is shown. The computer unit 222 includes a SCSI controller 224, which may include, for example, the circuit MB 86 601 manufactured by Fujitsu. Similar circuits are manufactured by NCR and others.

The SCSI controller 224 is connected to a multi-connector part 226 for connecting external SCSI devices. The connection between the SCSI controller 224 and the multi-connector portion 226 may be an internal bus 230 comprising a plurality of signal conductors. The internal bus 230 may comprise two sub-buses 232, 234, the first sub-bus 232 may comprise a plurality of data conductors and the second sub-bus 234 may comprise a plurality of control and monitoring signal conductors. The internal bus 230 may also be connected to a multi-connector portion 240 for connecting a first SCSI device internally to the computer unit 222.

According to one embodiment, the multi-connector part 240 can correspond to the previously described fourth multi-connector part 200, in an arrangement where the second computer unit 160 in Fig. 2 is constituted by the computer unit 222 described in Fig. 4.

Thus, the multi-connector portion 240 can be used to connect the computer unit 222 to other computer units. According to that embodiment, the multi-connector part 240 comprises at least one contact part 241 which is connected to the second signal level Uo.

The multi-connector part 240 further comprises a plurality of contact parts 242. The function of these contact parts 242 is well known to the person skilled in the art, which is why they are not described in more detail here. The internal bus 230 is further connected to inputs 246 of a controllable SCSI terminator 250. The controllable SCSI terminator 250 may be an integrated circuit, such as, for example, UC5601 manufactured by Unitrode. The controllable SCSI termination means 250 comprises termination means and is arranged to, depending on a control signal at a control input 260, either connect the inputs 245 to the termination means or break these connections.

The multi-connector part 226 comprises a plurality of contact parts 262. The normal function of these contact parts is well known to those skilled in the art, so they are not described in more detail here. However, according to the invention, a contact party has a distinctive function. The control signal at the control input one up 260 depends on the signal level of a control contact portion 270 of the multi-connector portion 226. When the multi-connector portion 226 is not connected to any external SCSI unit, the signal level at the control contact portion 270 is caused to maintain a high level by a resistor 280, the first connection of which is connected to a first signal level U1 and the second connection of which is connected to the contact portion 270 via the conductor 290.

The signal level U1 is preferably a voltage of + 5 volts, but can also be any other suitable signal level.

The second terminal of the resistor 280 is also connected to the input of an inverter means 300. The output of the inverter means 300 is connected to the control input 260 of the controllable SCSI terminator 250. Thus, when the signal level on the contact portion 270 is high, the inverter means causes the signal at control input 260 to be low, and thus the controllable SCSI terminator 250 engages the terminating resistors.

Conversely, when an external SCSI device is connected to the multi-connector part 226, the control contact part 270 contacts a contact part with the second signal level Uo. This causes the control contact part 270 to assume the signal level UC. The signal level UO is preferably a voltage level of zero volts or signal ground. When the control contact portion 270 receives a signal level UO of 12 volts, this causes the inverter means 300 to set the signal level on the control input 260 to a high signal level. The controllable SCSI termination means 250 thus disconnects the termination resistors.

The multi-connector portion 226 shown in Fig. 4 may, according to one embodiment, correspond to the previously described multi-connector portion 10B in Fig. 3. According to this embodiment, the multi-connector portion 226 comprises at least one contact portion 310 connected to the signal level Uo.

The invention thus entails a considerable simplification for the operator when connecting external SCSI units, and only a multi-conductor cable 120 'needs to be connected as an additional external unit 170 is to be chain-connected to the already connected units 150 and 160, as shown in Fig. 2.

Computer units provided with the arrangement according to the invention are also compatible with other standard computer units according to prior art. If the signal level Uo is selected for signal ground, the control contact part 50, 270 also receives a signal level Uo also from multi-contact devices according to the prior art. This means that if, for example, a peripheral unit according to the prior art is connected to the computer unit 170 in Fig. 2, the terminator means 70 "are disconnected.

Claims (8)

10 15 20 25 30 35 * f 13 ï; ~ ï_ Patent claim An arrangement at an interface at one end of a disconnectable conductor cable (120), the arrangement comprising: a first multi-connector portion (10; 226) and a second multi-connector portion (80) connectable to the first multi-connector portion, wherein the first the multi-connector part (10; 226) comprises a plurality of contact parts (20, 50) of which at least some contact parts (20) are connected to a data bus (40, 230), e.g. and s.k. SCSI bus, which requires termination means (70) connected to each of the bus conductors, when the multiconductor cable is disconnected, but not when connected, characterized by a sensing means (50,55,90; 270,280,300) for sensing whether the multi-conductor cable is connected to or disconnected, and a switching means (60; 250) controlled by the sensing means (50,55,90; 270,280,300) comprising a switch element (62) connected between each bus conductor and its associated termination means (70), the sensing means (50) , 55,90; 270,280,300) is arranged to control the switching means (60) to keep the switch elements (62) closed at disconnected multi-conductor cable and broken at connected multi-conductor cable. Arrangement according to claim 1, characterized in that the sensing means comprises at least one control contact part (50,270) specially set aside for the sensing purpose in the first multi-contact device part (10, 226) and a control signal source (Uo) connected to a contact part (100). in the second multi-connector part (80) connectable to the control contact part (50, 270), which control signal source provides such a control signal that the switching means (60; 250) is controlled to keep the switch elements (62) broken. Arrangement according to claim 2, characterized in that the switching means (60; 250) connects the termination means 10 15 20 25 30 35 -: 1 at: .fm -__'_ | C '* n; fifl f ”14 (70; 250) with the data bus (40; 230) when the signal level of the control contact part has a first value (U), and that the switching means (60; 250) disconnects the termination means (70; 250) from the data bus (40). ; 230) when the signal level on the control contact party has a second value (Uo). Arrangement according to claim 3, characterized in that the signal level of the control contact part (50) is caused to assume the second value (Uo) when the second multi-contact device part (80) is connected to the first multi-contact device part (10); and causing the signal level on the control contact portion (50) to assume the first value (U) when the second multi-connector portion (80) is not coupled to the first multi-connector portion (10; 226). Arrangement according to claim 4, characterized in that the first value and the second value are different voltage levels. Arrangement according to claim 1 or 2, characterized in that the first multi-connector part (10, 226), the data bus (40, 230), the switching means (60; 250) and the termination means (70,250) are included in a first computer unit (150); and that the second contact connector part (80) is connected via the fault conductor cable (120) to a second computer unit (160), the second computer unit comprising the control signal source (Uo). Arrangement according to claim 6, characterized in that the first computer unit is constituted by a data processing unit (150) and the second computer unit is constituted by a peripheral unit (160). Arrangement according to 6, characterized in that the first computer unit is constituted by a peripheral unit (160) and the second computer unit is constituted by a further peripheral unit (170).