DE19924127A1 - Communication network for the care sector - Google Patents

Abstract

A communication network for the care sector has network devices and a bus line (36, 42, 44, 46) that connects the network devices. In order to create a reliable and cost-effective network for different communication services in the care area, with which the security requirements in the care area are met, the network devices and the bus line (36, 42, 44, 46) are designed for digital, isochronous data transmission and the data transmission takes place in Data frames with a predetermined time period and a predetermined number of time periods for the arrangement of data, wherein in each data frame at least one time period is reserved for the arrangement of emergency call data.

Description

The invention relates to a communication network for the Care area with network devices and a bus line that connects the network devices.

Known communication networks for the care sector, such as for hospitals and nursing homes, for example for Call systems, telephone systems, radio programs and antennas were provided for TV sets (brochure "Communication Systems 1991 from Albert Ackermann GmbH & Co., Gummers Bach, printed note 943 / 6.91). Because of the between these individual communication services different data and the Each commu has various bandwidths required nication service via its own wiring. The parallel Laying cables for the different communica tion networks leads to considerable material and cost effort, for example, when equipping a hospital. In addition, there is a risk of mutual electromagnetic shear influence very large, which increases reliability the data transmission decreases.

Communication networks with digital are also known and isochronous or timely data transmission. Such Communication networks work according to the ISDN standard (Integrated Services Digital Network). Here  the data transmission takes place in data frames with predetermined Duration and predetermined number of periods, in where data is ordered. Data to be transferred arranged on sending network devices in the time segments net that are not yet occupied by data and are therefore free. Receiving network devices read this data from the times cut out or just copy them. Such communications However, networks are not for the high security requirements in the care sector because the immediate Wei not making an emergency call in all cases, e.g. B. at heavy network load, is ensured.

The aim of the invention is to be reliable and inexpensive Network for different communication services in the care area with which the security requirements are created requirements in the care area.

According to the invention, this is a communication network for the Care area with network devices and a bus line that connects the network devices, provided that the network work equipment and the bus line for a digital, isochronous Data transmission are designed and the data transmission in Data frames with a predetermined period of time and a predetermined on number of time periods for the arrangement of data takes place, wherein at least one time period for the arrangement of emergency data is reserved.

By using the network devices and the bus line for a digi tale, isochronous data transmission can network work devices of different communication services use shared network. As a result, a common Network for different communication services in the care area created and opposed to separate networks considerable material and cost savings, so through considerable Lich less installation effort possible. Opposite par Allel installed cable bundles of separate networks also increases the reliability of the data transmission, as there is no mutual electromagnetic influence on the parallel  Cable is to be feared. By reserving a time cuts in each data frame for the arrangement of emergency call data ten ensures that an emergency call is possible even in the Network load is immediately forwarded and the in Care area apply high security requirements can be filled.

In a further development of the invention it is provided that data un different communication services in different, predetermined periods are arranged. Hereby the transmission of digital data becomes more different Communication services facilitated and the reliability of the Transmission increased. For example, for the arrangement of Emergency, telephone, radio and other data each predetermined periods of time are provided. The data transfer network's transmission rate is then based on the transmission of Voice data designed, the data transfer rate so must be high that the simultaneous voice communication numerous participants can be transmitted.

As a further training measure, the Buslei device has a ring structure with at least one ring. The provision of a ring structure increases reliability of the network by basically dividing each network device into two Paths along the bus line can be reached.

A hierarchically graded group is particularly advantageous structure of the network, each group having a bus has line and is independently operable. A sol che group structure with independently operable groups enables high reliability of the network. Self in the event of failure of individual groups or the connection of the Groups among each other, network operation is still possible and especially emergency calls are made within and between the reliably forwarded still functional groups. For example, the structure can have main and sub-groups have, for example floors main groups and Pa  client rooms assigned to the main groups subgroups bil the.

As a further training measure it is provided that the Data transfer rate of individual groups is different. This allows the data transfer rate to the respective Requirements are adjusted so that in groups with low ren requirements for the data transfer rate, for example se patient room or individual parts of the building, the network can be realized more cost-effectively.

The formation of the bus line with is particularly advantageous Help optical guides. With optical conductors, a high Bandwidth can be achieved, and optical leaders are unemployed sensitive to electromagnetic interference. Simultaneously The galvanic isolation of the individual network areas becomes councils reached. Depending on the required data transfer rate, for example glass fibers or polymer fibers are used. Also beneficial is the application of bidirectional fibers, whereby Rich tion separation different emission colors, e.g. B. red / green, or a time-division multiplex method can be used.

This also makes the network highly reliable is enough that means to constantly monitor the function capability of the bus line are provided. Monitoring the Functionality can be caused, for example, by constant shutdown sending test data between the individual network devices take place, even if no communication data must be transferred. A possible failure of the buslei This enables early detection.

It is particularly advantageous if two lines per ring be provided and along a ring in front and behind we at least some of the network devices each have a means of optional connection of the two lines is provided. These measures enable an emergency bridging of the two Lines in the event of a line failure, which means even when the line is full  continuous interruption of a ring in the event of a fault closed by the emergency bridging and the functi ability of the network to be maintained.

It is also advantageous to provide means for constant monitoring of the functionality of at least one Part of the network devices. Such monitoring can also by constantly sending test data and evaluating the re action of the individual network devices take place, whereby a possible failure of a network device detected early can be.

It is also advantageous if a power supply for the network devices have a ring structure. In connection with a ring structure of the bus line the installation effort further reduced because bus line and power supply can be laid in a common cable and cable duct nen.

Finally, it is advantageous if at least one network device of the communication network with a 230 V mains voltage Operated terminal, the control of the end device via optical conductors. Such a terminal can, for example, an actuator for adjusting a patient tenbettes or a signal horn. By the control of the end device via optical conductors, is a galvanic separation between the network device of the communication Network and the one with mains voltage, for example 230 V, operated terminal ensured, which for safe loading drive of the network is contributed.

Further features and advantages of the invention result from the following description of a preferred embodiment the invention in connection with the drawing. In the Show drawing:

Fig. 1 is a schematic representation of a communication network, for the nursing field according to the invention

Fig. 2 is an illustration for explaining the principle used in data transmission in the communication network, and

Fig. 3 is a schematic representation of a network section with a disconnected bus line.

In Fig. 1 is a schematic system diagram of an embodiment of the communica tion be vorzugten network of the invention is illustrated for the nursing area. The hierarchical group structure of the network is well known. Three main groups 10 , 12 and 14 are shown , which are again connected via the main ring of the network 36 . Each of the main groups 10 and 12 are assigned to four sub-groups 16 , 18 , 20 and 22 or 24 , 26 , 28 and 30 . The main group 14 is only assigned to two sub-groups 32 and 34 . The number of main and sub-groups is in principle not limited, although the bandwidth of the network is a limit in practice. Each of the main groups and each of the sub-groups is operable on its own, so that communication remains possible even if a part of the groups fails.

The main ring of the network is formed by a building bus 36 , which consists of two plastic lightwave lenleitern laid in parallel. The data transfer rate on the building 36 is tuned to the expected amount of data to be transferred, which is mainly due to the number of voice channels to be transmitted simultaneously, e.g. B. phone calls and radio programs is determined. In this building bus 36 ver various network devices are integrated, so several Datenzentra len DAZ at the connection points of the main islands 10 , 12 and 14 as well as a telephone connection center TAZ and an ELA connection central EAZ. At the telephone connection center TAZ, the building bus 36 is connected to a telecommunications system TK. At the ELA connection center EAZ audio data, e.g. B. Ra dioprogramme, fed into the building bus 36 . The data center DAZ 38 is connected via a server PC to a data processing system DV. Also connected to the DAZ 38 data center is a cash machine K, at which the patient can identify himself with the aid of an identification card and deposit money into an account. From this account managed in the billing server PC 40 , the patient's use of certain services, e.g. B. television programs, fees to be paid.

The main group 10 is constructed in the same way as the main group 12 and has a floor bus 42 which has two parallel, ring-shaped plastic optical waveguides. Since the expected amount of data to be transmitted on the floor bus 42 is less than on the building bus 36 , more cost-effective optical fibers or less powerful interface devices can be selected here. A number of room terminals ZT, to which the auxiliary groups 16 , 20 and 22 are connected, are integrated in the floor bus 42 . The auxiliary group 18 is connected via a DZT duty room terminal also integrated into the floor bus 42 . Furthermore, a light unit L is integrated in the floor bus 42 . The lighting unit L is arranged on the floor of the factory floor in front of a patient room and, for example, indicates a call to the nursing staff triggered by a patient. The power supply of the integrated in the cane plant bus 42 network devices DAZ, ZT, DZT also has an annular structure and is installed parallel to the Stockwerksbus 42nd

The sub-groups 16 , 20 and 22 are constructed identically and each have a room bus, which consists of a ring-shaped optical fiber and is designated 44 in the case of sub-group 16 . In addition to the room terminal ZT, two better terminals BT are integrated into the room bus 44 , each of which is arranged next to a patient bed and therefore allows access to the network with a patient. Here too, the possible number of Betterminals BT in the room bus 44 is only limited by the maximum possible data transmission rate on the room bus 44 .

The room bus of the sub-group 18 is constructed immediately to the room bus 44 , the sub-group 18 being in a service room in which a telephone T and a personal computer PC are integrated into the room bus. The nursing staff can thus access the data processing system DV from the duty room via the personal computer PC and the network, for example.

The main group 14 is shown in more detail and has a floor bus 46 connected to the building bus 36 via a data center DAZ. In the floor bus 46 is a lamp 48 , which is arranged in front of a patient's room and indicates a call of a patient to the nursing staff. Furthermore, an electronics module 50 with an intercom 52 is connected to the room bus 46 . A display 54 shows, for example, the room number from which a patient's call comes, or only the current time. Furthermore, the display 54 is provided with loudspeakers for the announcement of messages. With the reference sign 56 , a directional light is designated, which is arranged on the floor and indicates the direction in which a patient's room can be found, from which a call was placed. The lights 48 and 56 , the displays 54 and the light units L in the main islands 10 and 12 are part of a so-called light call system that uses the common network for data transmission.

The sub-group 34 arranged in a patient room is connected to the floor bus 46 via a room terminal ZT and has two Better terminals BT. At the Better terminal 58 , a television set TV and a control unit B are closed. Using the control unit B, a patient can use the various communication services offered, for example select radio and television programs, make phone calls and make calls to nursing staff and make emergency calls.

FIG. 2 explains the principle used for data transmission in the network of FIG. 1. An isochronous or timely data transmission is achieved with the help of a data frame structure. A data frame 60 extends over a period of 125 microseconds and is divided into n time segments. In these n time periods, digital data are arranged or taken or copied from the network devices in the network. A time period 62 in each data frame 60 is reserved for emergency data N. In this period 62 only emergency data N may accordingly be arranged so that even with heavy network load, in which all other periods of a data frame may be occupied, the immediate forwarding of an emergency call is ensured. The reservation of the time segment 62 in each data frame 60 for emergency call data N creates the prerequisites that the high security requirements to be made for emergency call communication in the care area are reliably fulfilled. Additional time periods in each data frame 60 are provided for the arrangement of data from other communication services that use the common network. Thus, the time segment 64 is provided for telephone call data T, whereas in the time segments 66 only radio program data R and in the time segments 68 other data S, such as data for billing, etc., are arranged.

FIG. 3 shows schematically the functional principle of the means provided in the embodiment of FIG. 1, with which further communication is ensured in the event of a fault in the event of a ring bus line being interrupted. For example, a section of the building bus 36 forming a ring is shown, which has two optical fibers 70 and 72 and in which two network devices 74 and 76 , for example the telephone connection center TAZ and a data connection center DAZ, are integrated. Between the network devices 74 and 76 , both optical fibers 70 and 72 are interrupted at a point X. Such a complete separation of the ring of the building bus 36 can occur, for example, when improperly installed. A switch 78 , 80 , 82 and 84 is arranged in front of and behind the network devices 74 and 76 , respectively. These switches 78 , 80 , 82 and 84 can each of control devices, which are hen in the network devices 74 and 76 , selectively closed or opened and thus connect or disconnect the optical fibers 70 and 72 . In the operation of the network, the functionality of the building bus 36 is continuously monitored by continuously exchanging test data between the network devices 74 and 76 . The functionality of the network devices themselves is constantly monitored during the operation of the communication network by exchanging test data. If a failure of the network devices 74 and 76 of the building bus 36 between network devices 74 and 76 detected include the Ansteuereinrich obligations in the network devices 74 and 76, the switches 80 and 82 as shown in FIG. 3 is shown. As a result, the Ge building bus 36 is closed again to a ring, which now runs over the optical waveguide 70 , the switch 82 , the optical waveguide 72 , the switch 80 and again to the Lichtwellenlei ter 70 .

Also shown in FIG. 3 is a device 86 connected to the network 74 , which is operated with the mains voltage of 230 V. The terminal device 86 is controlled by the network device 74 via an optical waveguide 88 . In this way, the electrical isolation between network device 74 and terminal 86 is ensured.

Claims (11)

1. Communication network for the care sector with network devices and a bus line ( 36 , 42 , 44 , 46 ) that connects the network devices, characterized in that the network devices and the bus line ( 36 , 42 , 44 , 46 ) for a digital, isochronous Data transmission are designed and the data transmission in data frames ( 60 ) with a predetermined time duration and a predetermined number (n) of time periods ( 62 , 64 , 66 , 68 ) for the arrangement of data (T, R, N, S) takes place, wherein in at least one time segment ( 62 ) is reserved for the arrangement of emergency call data (N) for each data frame ( 60 ). 2. Communication network according to claim 1, characterized in that data (T, R, N, S) different communication services in different, predetermined Zeitab sections ( 62 , 64 , 66 , 68 ) are arranged. 3. Communication network according to one of the preceding claims, characterized in that the bus line ( 36 , 42 , 44 , 46 ) has a ring structure with at least one ring. 4. Communication network according to one of the preceding claims, characterized in that the network has an archic group structure here, each group ( 10 , 12 , 14 , 16 , 18 , 20 , 22 , 24 , 26 , 28 , 30 , 32 , 34 ) has a bus line ( 36 , 42 , 44 , 46 ) and is independently operable. 5. Communication network according to claim 4, characterized in that the data transfer rate of individual groups ( 10 , 12 , 14 , 16 , 18 , 20 , 22 , 24 , 26 , 28 , 30 , 32 , 34 ) is different. 6. Communication network according to one of the preceding claims, characterized in that the bus line ( 36 , 42 , 44 , 46 ) is formed with the aid of optical conductors ( 70 , 72 ). 7. Communication network according to one of the preceding claims, characterized in that means for continuously monitoring the functionality of the bus line ( 36 , 42 , 44 , 46 ) are provided. 8. Communication network according to claim 3 and one of claims 4 to 7, characterized in that two lines ( 70 , 72 ) per ring and along the ring in front and behind little least a part of the network devices ( 74 , 76 ) each with a tel ( 78 , 80 , 82 , 84 ) for selectively connecting the two lines ( 70 , 72 ) is provided. 9. Communication network according to one of the preceding An sayings, characterized in that means for permanent Monitor the functionality of at least a portion of the Network devices are provided. 10. Communication network according to one of the preceding An sayings, characterized in that a power supply for the network devices have a ring structure. 11. Communication network according to one of the preceding claims, characterized in that at least one network device ( 74 ) has an actuator operated at mains voltage ( 86 ), the actuation of the actuator ( 86 ) via optical conductors ( 88 ).