WO1994006225A1 - System integrating a plurality of electrical items and connector block for use with such a system - Google Patents

Abstract

In a system, several electric items (10, 12, 14, 16) of various types are connected each by an interface to a common bus constituted by fiber optic sections (18, 20, 22, 24) and which forms a closed ring. Each apparatus is connected to the bus by a connector block (30). The connector block (30) has electric contacts for connecting with the respective apparatus, a fiber optic input and a fiber optic output inserted between two fiber optic sections (18, 20, 22, 24). The connector block (30) contains two electrooptical transducers for converting optical signals arriving via the bus into electric signals and for converting electric signals coming from the electric contacts into optical signals transmitted via the bus. In order to ensure the integrity of the whole bus system even when an item breaks down, the optical path inside each connector block (30) is automatically bridged when the connected apparatus is faulty or when no apparatus is connected. As bridging element a concentrating reflector (118) may be used.

Description

 Subscriber system with several subscribers formed by electrical devices and connector block for use in such a subscriber system

The invention relates to a subscriber system with a plurality of subscribers formed by electrical devices, each of which is connected via an interface to a common bus formed by optical waveguides.

In such a subscriber system, various types of electrical and electronic devices are networked with one another and exchange information with one another via the common bus. For example, in motor vehicles, audio signal sources such as radio receivers, cassette recorders or CD players are connected to one another on the one hand and to audio sinks such as amplifier / speaker combinations on the other hand. Device components that are used for extensive control and monitoring of vehicle functions can also be integrated into such a network. So that all participants in the system can communicate with one another, the bus is preferably designed as a loop in itself. Each subscriber component is therefore connected to an incoming fiber optic cable. cut and connected to an outgoing optical fiber section. In the interface of each subscriber component, the incoming light signals are converted into electrical signals, evaluated and modified if necessary, and then converted into optical signals which are forwarded via the outgoing optical waveguide section. The light path is therefore interrupted at each individual subscriber component and is bridged by the function of the relevant subscriber component with its interface containing the electro-optical converters with respect to the signal flow.

In such a subscriber system, there is initially a need for the simple and flexible coupling of different subscriber components by means of a uniform connection concept. This is achieved in the subscriber system according to the invention in that the interfaces each comprise a connector block, which has electrical contacts for connection to the associated device, an optical waveguide input and an optical waveguide output for insertion into the optical waveguide, and in that the optical waveguide input has an electro-optical converter For converting light signals arriving via the bus into electrical signals passed on to the electrical contacts and the optical waveguide output, an electro-optical converter for converting the electrical signals coming from the electrical contacts into light signals going out on the bus is assigned. In the subscriber system according to the invention, important interface functions are therefore shifted to the connector block. The individual devices therefore do not have to be designed for operation on an optical bus system. The optical waveguide forms a closed system with the individual connector blocks, which communicates to the outside only via electrical contacts. The connector blocks can be designed as uniform standard plug connection parts, so that the subscriber devices provided with a complementary plug connection element can be connected to the common bus system solely by establishing a single plug connection. However, if any subscriber component fails in a subscriber system with a closed bus, the signal flow on the entire bus is interrupted and the entire subscriber system can fail. This is a consequence of the monodirectional signal transmission from one subscriber component to the next, and because of the interruption of the optical signal path at each subscriber component, their perfect functioning must be assumed at least with regard to the reception and transmission of signals.

In the subscriber system according to the invention, this problem is remedied by the fact that in the connector block the optical path between the optical waveguide input and the optical waveguide output is bridged when no electrical device is connected or is defective, and is interrupted when an electrical device is connected and is functional. At rest, i.e. if the device is not connected or the device is inactive, the optical waveguide is bridged within the connector, so that signal transmission is ensured. Only a device connected to the connector block and functional at least with regard to signal reception and transmission can cause an interruption in the optical path within a connector block.

According to an advantageous development, a suitable connector block contains an optical switch between the optical waveguide input and the optical waveguide output. This optical switch can assume two switching states, namely a first state in which the optical path between the optical waveguide input and the optical waveguide output is bridged, and a second switching state in which the optical path between the optical waveguide input and the optical waveguide output is interrupted. In the idle state, the switch assumes the first switching state; the switch can be reversed into its second switching state only by a control signal coming from the associated device. If the device like this It is conceived that the control signal can only be emitted if at least its function of signal acceptance and signal transmission is guaranteed, the function of the entire bus system is not endangered by the failure of an individual subscriber component.

If the optical waveguides are not made of glass fibers, but of plastic, an optimal loss minimization must be ensured in a subscriber system, since the plastic already has a relatively high internal attenuation for the light to be transmitted. An advantageous development of the invention, which is particularly suitable for this application, is embodied in a connector block in which the optical deflection means is formed by a concave mirror, which in the first position of the optical switch is thus relative to the ends of the optical waveguides is arranged such that it reflects the light coming from the input waveguide into the output waveguide. The concave mirror can produce an almost lossless connection between the two ends of the optical waveguides, so that this component is particularly suitable when the lowest possible losses are aimed for. In a further embodiment of the invention, the connector block can be used as a switch-like component in a bus system, with which, depending on the position of the optical switch, a bus can be closed or coupled to another bus.

In a further embodiment of the invention, the connector block can be used as a switch-like component in one Bus system can be used with which, depending on the position of the optical switch, a bus can be closed or coupled to another bus.

Advantageous developments of the invention are specified in the subclaims.

Further features and advantages of the invention result from the following description of an embodiment of the subscriber system and from the drawing to which reference is made. The drawing shows:

1 schematically shows a bus system closed to a ring, the bus of which is designed as an optical waveguide, to which four subscriber components are connected;

2 shows a connector block connected to a subscriber component, which is used in the subscriber system;

3 shows the connector block detached from the subscriber component;

4 shows a schematic representation of a possible embodiment of an optical switch for the connector block;

5 shows a variant of the connector block; 6 shows a side view of a connector block according to a further embodiment of the invention;

7 shows the optical switch of the connector block from FIG. 6 in its second switching state in association with the electronic module;

8 shows the optical switch from FIG. 6 in its first switching state;

Fig. 9 is a section along the line 9-9 of Fig. 8;

FIG. 10 shows a schematic, partially sectioned view of the connector block from FIG. 6 from below; FIG.

FIG. 11 shows a schematic, partially sectioned view of the connector block from FIG. 6 from the left; FIG.

12 shows a further embodiment of a connector block according to the invention;

Fig. 13 is a schematic representation for explaining the

Switching options of the connector block of Figure 12, wherein the bridging element of the optical switch is in the second position.

Fig. 14 is a similar representation as in Fig. 13, but with the bridging element of the optical switch in the first position, and

15 shows an advantageous further development of the bridging element. In the subscriber system shown schematically in FIG. 1, four subscriber components 10, 12, 14, 16, which are electrical or electronic devices, are connected to a common bus which is closed to form a ring and which consists of four optical waveguide sections 18, 20, 22 , 24 exists. The connection of each subscriber component 10, 12, 14, 16 takes place by means of a connector block 30, which is of the same design for all subscriber components and has an optical waveguide input 30a and an optical waveguide output 30b (FIGS. 2, 3 and 5). Each connector block 30 also has a series of electrical contacts which serve to connect to the associated subscriber component. In the embodiment shown in Figures 1, 2 and 3, five electrical contacts are provided, which have the following function:

A first contact 1 carries a ground potential;

a second contact 2 carries the electrical signals to be applied to the relevant electrical or electronic device;

a third contact 3 carries the electrical signals coming from the device;

a fourth contact 4 carries a supply voltage;

a fifth contact 5 carries a control signal from the connected device to the connector block 30.

The connector block 30 contains two electro-optical converters 40, 42. The first electro-optical converter 40 converts the optical signals arriving via an optical waveguide section into electrical signals which are output at the electrical contact 2. The second electro-optical converter 42 sets the electrical signals arriving at the electrical contact 3. trical _S ignale into optical signals which are fed to the optical waveguide section in the exit ^¬.

Each connector block 30 is also equipped with an optical ^switch . This generally indicated in Figures 2 and 3 with 50 optical switch comprises a translatable optical waveguide section 52, a Spiegel¬ body 54 with two right angle surfaces ^¬ forming Spiegelflä, which coupled with the optical waveguide section 52

and an electromagnetic drive 56 which can be controlled by the control signal present between the electrical contacts 1 and 5. In the de-energized state of the electromagnetic drive 56, for example when the connector block is detached from the device 14 in question (FIGS. 1 and 3), the optical waveguide section 52 is in a position in which it connects the optical waveguide input 30a to the optical waveguide output 30b, so that a close ¬ To lossless transmission of the optical signals through the connector block 30 takes place. Only when the connector block is plugged in and a control signal is present between the electrical contacts 1 and 5 is the electromagnetic drive 56 excited and moves the optical waveguide section 52 with the mirror body 54 into the position shown in FIG. 2, in which the optical path between the Optical waveguide input 30a and the optical waveguide output 30b is interrupted. In this position, however, the mirror body 54 with its two mirror surfaces standing at right angles to one another deflects the light paths from the optical waveguide input 30a to the electro-optical converter 40 and from the electro-optical converter 42 to the optical waveguide output 30b. The continuity of the signal transmission is now guaranteed by the respectively connected electrical or electronic device. If one of the devices connected in this way becomes defective, the control signal for the electromagnetic drive also disappears in the connector block, so that the optical switch automatically returns to the idle state shown in FIG. 3. Various designs are possible for the optical switch 50. FIG. 4 shows an alternative to the embodiment shown in FIGS. 1 to 3. In the embodiment according to FIG. 4, the light beam coming from the optical waveguide input 30a enters perpendicularly into the large base area of a generally trapezoidal prism 60 which consists of two symmetrical parts 60a, 60b. The incident light beam undergoes total reflection on the inside of the adjacent inclined surface of prism part 60a and is deflected perpendicular to the direction of incidence until it hits the inside of the opposite inclined surface of prism part 60b and is deflected there by total reflection parallel to the incoming beam and emerges perpendicularly from the large base area of the prism 60. In the narrow gap through which the prism parts 60a, 60b are separated, however, an optical shutter 62 is slidably arranged. The optical closure 62 is moved into and out of this gap by an electromechanical drive 64. The electro-optical converter 40 is arranged on the inclined surface of the prism part 60a and the electro-optical converter 42 on the inclined surface of the prism part 60b. Depending on the position of the optical shutter 62, the optical signal path between the incoming and outgoing light beam is interrupted or switched through.

In a variant of the embodiment shown in FIG. 4, the prism is generally diamond-shaped with parallel inclined surfaces, so that the incoming light beam emerges from the prism offset in parallel in the same direction.

Other possible designs of an electro-optical switch are based on various electro-optical effects, so that mechanically moving parts can be omitted, for example the use of liquid crystals which can be controlled directly by an electrical signal. In the embodiment of a connector block shown in FIG. 5, in addition to the five contacts previously assumed, two further contacts 6, 7 are provided, which serve to supply a supply voltage to the various subscriber components. The operating voltage for the electro-optical converters 40, 42 and the drive 56 of the connector block 30 can be derived from this supply voltage between the electrical contacts 1 and 4. The Kon¬ nektorblock 30 thus has the electrical contacts 1 to 7 and is connected to the optical fiber sections 20, 22 and two electrical conductors 70, 72. All elements of the connector block 30 can be integrated into a standardized connector housing, so that the electrical or electronic devices to be connected need only be equipped with a complementary connector part.

It goes without saying that the number of subscriber components can be significantly larger than in the example assumed in FIG. 1.

Another embodiment of a connector block is shown in FIG. 6. This connector block 100 has a housing 102 which is provided with electrical connections 104a and 104b and with connections 106 for optical waveguides. The electrical connections 104a lead to an electronics module 108 which has an electro-optical converter for converting incoming light signals into electrical signals and a further electro-optical converter for converting electrical signals into light signals. An optical switch 110 is inserted between the ends of the optical waveguide connections 106 and the electronic module 108 and can be moved between an upper switch position and a lower switch position, which is also accommodated in the housing 101, by means of a relay 112. In the upper formwork shown in FIG. There is a direct light-conducting connection between the ends of the optical waveguide connections 106 and the electro-optical converters in the electronics module 108; this connection can be made by attaching two short optical fiber sections 114 in switch 110, which in the switch position of FIG. 6 lie in line with the ends of optical fiber connectors 106 and the electro-optical converters in electronics module 108. In a simple embodiment, the optical waveguide sections 114 could simply be replaced by holes in the switch 110.

6 is when the relay 112 is supplied with an electrical switching signal via the electrical connections 104b. On the other hand, if there is no switching signal at the relay 112, the armature lever 116 connected to the switch 110 lowers the optical switch 110 under the action of a preload spring (not shown), so that the section of the switch 110 marked 118 is in line with the ends of the optical waveguide connections 106 is brought.

The two positions of the electro-optical switch 110 relative to the electronic module 108 are shown in FIG. 7 and in FIG. 8. It should be noted that these two components are viewed from the left as shown in FIG. 6, which means that the ends of the optical waveguide connections 106 lie in front of the plane of the drawing.

In the position of FIG. 7, the electro-optical switch 110 is located with respect to the electronics module 108 such that there is a direct light connection between the ends of the optical waveguide connections 106 and the transducers in the electronics module 108.

In contrast, in the position of FIG. 8, the section of the switch 110 designated 118 is in line with the ends of the optical waveguides 106. The section of FIG. 9 shows how the section 118 of the electro-optical switch 110 is designed. It can be seen from this that the section 118 has a spherically curved region which, in the switch position of FIG. 8, lies opposite the ends of the optical waveguide terminations 106. This spherical area is designed as a concave mirror surface, so that light that strikes this area is reflected again. By appropriately dimensioning the radius of curvature and the distance between the ends of the optical waveguide connections 106, it can be achieved that the light coming from one optical waveguide and striking the spherical surface is completely reflected in the other optical waveguide. This reflection takes place with very little loss. This is particularly important if the optical waveguides are not made from glass fibers but from plastic, so that they have a relatively high internal attenuation; In this case, any additional damping caused in the bus system by coupling, decoupling or any switching operations must be kept as low as possible. A subscriber system with optical fibers made of plastic can only be used in practice if the entire system is very carefully designed to minimize losses.

6 can also be used to couple an electronic device to the bus in the manner already described above, wherein continuity of the bus is ensured if no device is connected or an error occurs in the device. in which the optical switch 110 assumes the position in which the region acting as a hollow mirror is opposite the ends of the optical waveguide connections. Only when an electronic device is to be coupled to the bus and this device also works properly, does a switching signal reach the electrical connections 104b of the connector block, which excites the relay 112 and causes the optical switch 110 to be moved to the position in FIG. 7. FIGS. 10 and 11 show views of the connector block from FIG. 6 from below and from the left, with the housing in particular being cut open so that the essential parts can be better seen. 11, the switch 110 assumes the same position as in FIG. 7.

Another embodiment of a connector block is shown in FIG. 12. In this embodiment, the connector block can be used as a switch or as a switch in a bus. In the illustration of FIG. 12, it is provided with two optical fiber connections on the left side and on the right side. In the housing 120 of this connector block, as in the previous embodiments, there is a relay 122, with the aid of which an optical switch 124 is switched from the rest position shown in FIG. 12, in which the relay 122 is not energized, to a working position when the relay is energized ¬ tet in which it is shifted downwards compared to the representation of FIG. 12. In the position shown in FIG. 12 there are openings in a line with the ends of the optical waveguide connections in the optical switch 124 which allow the light to pass through unhindered. In the excited state of the relay 122, a spherical mirror surface on the optical switch 124 is brought into a position opposite to the ends of the optical fiber connections on the left side of the housing, so that the optical fibers which are connected on the right side are decoupled.

Which switching operations can be achieved is explained with reference to FIGS. 13 and 14. In Fig. 13, the input E1 and the output AI are connected directly to the bus of the subscriber system, while the input E2 and the output A2 are connected to an electronic device to be coupled to the bus. In the position of the switch of FIG. 13, the light coming from the input E1 can go directly to the output A2 and thus to the electronic device. while the signal emitted by the electronic device can be coupled via input E2 to output AI and thus to the bus. If, on the other hand, no electronic device is connected, the switch 124 is brought into the position in FIG. 14, in which the light coming from the input E1 is reflected directly into the output A2 via the spherical surface acting as a concave mirror. In this way, the bus is closed by switch 124 almost without loss.

A development of the optical switch 124 is shown in FIG. 15. With this configuration, it is possible to either close two buses, which are connected to the input E1 and the output A2 or the input E2 and the output A2, (position of the switch 124 according to FIG. 15) or also directly to one another couple. In the position of FIG. 15, the light coming from the input E1 is reflected to the output AI, and the light coming from the input E2 is reflected into the output A2. In contrast, in the position of the switch 124 (not shown) which corresponds to the position in FIG. 13, the light from the input E1 goes directly to the output A2, while the light from the input E2 to the output AI. This means the coupling of two buses.

Claims

Patent claims

1. Subscriber system with a plurality of subscribers formed by electrical devices (10, 12, 14, 16), each of which is connected via an interface to a common bus formed by an optical waveguide (18, 20, 22, 24) that the interfaces each comprise a connector block (30; 100) which has electrical contacts (1, 2, 3, 4, 5, 6, 7; 104a) for connection to the associated device (10, 12, 14, 16 ), an optical waveguide input (30a) and an optical waveguide output (30b) for insertion into the optical waveguide (18, 20, 22, 24; 106), and that the optical waveguide input (30a) has an electro-optical converter (40) for converting via the bus incoming light signals in electrical signals forwarded to the electrical contacts (2) and the optical fiber output (30b) an electro-optical converter (42) for converting the electrical signals coming from the electrical contacts (3) into Lic is assigned.

2. Subscriber system according to claim 1, characterized in that the bus (18, 20, 22, 24) forms a closed loop on which the light signals are transmitted monodirectionally.

3. Subscriber system according to claim 1 or 2, characterized gekenn¬ characterized in that in the connector block (30; 100) the optical path between the optical waveguide input (30a) and optical waveguide output (30b) is bridged when no electrical device (10, 12, 14, 16) is connected or this is defective, and is interrupted when an electrical device is connected and working.

4. Connector block for use in a subscriber system according to one of the preceding claims, characterized gekennzeich¬ net that it is formed as a standardized connector part and at least the following electrical contacts

- a ground connection (1),

- at least one power supply connection (4, 6, 7),

- A signal input (2) and

- a signal output (3)

and furthermore has two optical waveguide connections (30a, 30b) and two electro-optical converters (40, 42).

5. Connector block according to claim 4, characterized in that an optical switch (50) is arranged between the light waveguide input (30a) and the light waveguide output (30b), that this switch (50) can assume two switching states,

a first switching state in which the optical path between the optical waveguide input (30a) and optical waveguide output (30b) is bridged, and

- a second switching state in which the optical path between the optical fiber input (30a) and optical fiber output (30b) is interrupted;

that the switch (50) assumes the first switching state in the idle state and can be switched to the second switching state by a control signal coming from the associated device (10, 12, 14, 16) and that the electrical contacts have a further connection (5) for include the control signal.

6. Connector block according to claim 5, characterized. that the optical switch (50) has an optical bridging element (52) which mechanically between a first position in which it connects the optical fiber input (30a) to the optical fiber output (30b) and a second position in which it interrupts the optical path between the optical waveguide input (30a) and the optical waveguide output (30b).

7. Connector block according to claim 6, characterized in that the optical bridging element is formed by a movable light guide section (52) and with this coupled optical deflection means (54) which deflect the optical path to the electro-optical converters (40, 42).

8. Connector block according to claim 5, characterized in that the optical switch has an optical bridging element (60) which is arranged in a fixed position between the optical waveguide connections and a controllable optical closure (62) and optical deflection means for beam deflection to the electro-optical converters (40, 42).

9. Connector block according to claim 7 or 8, characterized gekenn¬ characterized in that the optical deflection means are formed by mirror surfaces.

10. Connector block according to claim 7 or 8, characterized gekenn¬ characterized in that the optical deflection means are formed by totally reflecting surfaces.

11. Connector block according to claim 6, characterized in that the optical bridging element has a concave mirror (118) which, in the first position of the optical bridging element, is arranged relative to the ends of the optical waveguide (106) in such a way that that of the input waveguide ¬ ter incoming light is reflected in the output waveguide.

12. Connector block for use in a subscriber system according to one of claims 1 to 3, characterized. that it has at least two optical fiber connections (106), one as an input connection (El) and one as an output connection (AI), that the two optical fiber connections are assigned an optical switch (124) which can be controlled in such a way that it has two Switching states can assume, namely

- A first switching state in which the optical path between the input connection (El) and the output connection (AI) is bridged, and

a second switching state in which the optical path between the input connection (El) and the output connection (AI) is interrupted,

- The switch (124) assuming the first switch state in the idle state.

13. Connector block according to claim 12, characterized in that the optical switch (124) has an optical bridging element that mechanically between a first position, in which it connects the input connection (El) with the output connection (AI) , and a second position in which it interrupts the optical path between the input connection (El) and the output connection (AI), and which has a concave mirror (118) which, in the first position of the bridging element, is thus relative to the ends the optical waveguide (106) is arranged so that the light coming from the input connection (El) is reflected into the output connection (AI).