SE535835C2 - Method and apparatus for communication over electrical distribution network - Google Patents

Abstract

Method and device for communication via an electricity distribution network (10) in an establishment, whereby data signals are transmitted via network nodes connected to the electricity distribution network. Information about the physical location of the network nodes (11 ) and a unique identity for each network node (11 ) are stored in a storage unit (17) of a central unit (16) which is connected to the network nodes (11 ; 20). Certain network nodes (11 ) are wirelessly connected to mobile units (13; 14; 15; 27; 28; 29) and communication between the mobile units (13; 14; 15; 27; 28; 29) takes place via network nodes (11 ) and the electricity distribution network (10). Information exchanged between the mobile units (13; 14; 15; 27; 28; 29) is recorded and stored in the central unit (16). The central unit (16) is designed to convey necessary addressing in¬ formation to the network nodes and comprises a storage unit for recording and storing such communication information exchanged between the network nodes. A built-in network node (38) in an appliance (39) communicates with, controls and monitors via units (40-44) a piece of equipment connected to an electricity distribution network.

Description

25 30 535 835 2 connected to each other and to a main unit via a permanent mains. A modem (modulator / modulator) connects the devices and the device to the mains.

The systems that are available today are based on independent units that communicate with each other in smaller networks, or in smaller groups. There are problems with organizing and configuring larger networks with reliable monitoring and control. In a hospital environment and in many other similar environments, such as municipal care, hotels and premises for manufacturing and trade, cabling to rooms for various purposes and functions entails major problems and entails large costs. When the environment is redesigned and rooms and spaces are given other functions, it is usually necessary to redraw cabling and install new forms of networks, which entails additional costs.

SUMMARY OF THE INVENTION An object of the invention is to provide a larger and more flexible system for efficient communication within defined areas. A demarcated area refers to a facility with one or several buildings. Several facilities can work together and thus constitute a delimited area.

Another purpose of the invention is to provide systems for handling and transmitting messages and various alarm functions.

Another purpose of the invention is to provide systems for secure monitoring of various forms of patient alarms, technical alarms and for the transmission of critical information to and from staff in hospital settings. Monitoring of patients can take place with patient-connected control equipment, which can also allow position determination of the patient. Furthermore, systems constructed in accordance with the invention can be used to control and monitor technical equipment, such as fans, dialysis equipment, motors, passage alarms, and more.

These purposes are achieved by utilizing the existing electrical distribution network on premises and connecting network nodes to this. The network nodes may be provided with a suitable means for wireless data communication, e.g. systems based on Bluetooth®, standards within IEEE 802.11, IEEE 802.16 (WiMax), DECT (Digital European Cordless Telephone), lrDA (Infrared Data Association) and the like. Different types of communicators act as terminals in the system. A central unit with archive function controls, monitors and refines the communication between terminals and network nodes.

The electrical distribution network is preferably arranged in a facility with a building or a number of adjacent buildings. The electricity network is usually of a standard type in different environments and usually remains unchanged, even if the function of a room or a room changes. Different filters and attenuation kits are used to delimit the communication to the desired area. Different delimited areas can be connected to larger contiguous units with several central units. The various central units can then cooperate with each other and function as redundant units. Each individual network node is provided with a unique identity that is assigned or at least known by the central unit.

It is also possible in this context to use the technology called ADSL (Asymmetric Digital Subscriber Line) for data transmission on two-wire copper wire. In accordance with this technology, data signals are superimposed on the electrical voltage signal.

The network nodes can be connected in ordinary wall sockets and are then preferably fixed, e.g. through the screws normally used to mount the wall socket. By being attached, the network node is moved inadvertently or incorrectly. It is also possible to connect the network nodes to the electrical distribution network. This happens, for example. in roof installations and in installations of a more fixed nature. As an alternative, possibly in combination with the above, the network nodes can be built into electrically connected equipment. In each room of the building or buildings, at least one network node is preferably arranged. Patients in the room have access to or carry an alarm transmitter or alarm device, which is wirelessly connected to the network node.

The alarm transmitter and the alarm unit are associated with a specific patient and in the event of an alarm, the central unit can determine both from which patient and from which room the alarm comes. Other technical equipment, which is connected to network nodes, is also uniquely identified.

Personnel in the building or buildings have access to or carry handsets of various kinds, which may include bodies that enable position determination. The handsets are wirelessly connected to the network nodes.

Via the central unit, a connection can be established between the patients' alarm transmitters and the staff's handsets, whereby alarms can be received and processed by suitable staff. It is also possible to send different types of response signals from the handsets and thereby partly confirm the receipt of an alarm signal and partly send some form of response to the patient's alarm transmitter, e.g. that staff is on the way. For this exchange of information, alarm transmitters and handsets can be equipped with simpler or more complex indicators and displays. In well-developed designs in accordance with the invention, patients, staff and connected technical devices exchange qualified information in various forms with the central unit. The central unit can be divided into several physical units, both in different buildings and in different facilities.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with the aid of exemplary embodiments with reference to the accompanying drawings, in which Fig. 1 is a schematic overview view of an installation in accordance with the invention, Fig. 2 is a schematic view of a part of an installation in accordance with the invention, Fig. 3 schematically shows an embodiment of a network node used in Fig. 1 and Fig. 4 schematically shows an embodiment of an apparatus with a built-in network node. 10 15 20 25 30 535 B35 5 THE INVENTION Fig. 1 shows an example of an installation carried out in accordance with the invention. A physical network connects and enables communication between electronic nodes and network devices. The physical network consists of a conventional electrical distribution network 10, usually with an operating voltage of 230V or 115V AC, and is called an electrical network. the installation is limited to a facility, which may include fl your buildings. The delimitation is achieved with filters or attenuator sets 36, which may be of a conventional type.

A number of network nodes 11 are connected to the electrical distribution network 10, including electrical and electronic components for modulating and demodulating data signals on the alternating voltage in the electricity network. The network nodes enable data communication between different forms of computer equipment, for example computers, printers. and digital surveillance cameras. I den i F ig. The application shown in Fig. 1 is also a number of mobile units specially adapted for hospital environments, hotel environments and other similar environments connected to the network nodes 11. Such adapted units include a monitoring unit 12, an alarm transmitter 13, a handset 14 and an alarm indicator 15. Within the framework of the invention may have additional units with similar functions.

A very simple design of a network node 11 may comprise a tar-controlled electrical switch, which is a commercially available and inexpensive product. A stand-alone, preferably handheld, device communicates wirelessly with a networked device. With the aid of the stand-alone unit, electrical appliances connected to the mains-connected unit can be activated or, in the current application, an alarm signal or the like can be sent via the electrical distribution network. In the simplest embodiment, the network node 11 is provided with a push button for transmitting an alarm signal or the like. The network node can also be equipped with a light or other indicator that indicates that the button has been pressed.

The network nodes 11 are controlled and monitored by a central unit 16 connected to the electrical distribution network 10 with associated peripherals such as archive or storage unit 17, keyboard 18 and monitor 19. The central unit 16 is designed to administer the communication between the network nodes 11 and ensure that all network nodes 11 belonging to the installation are correctly identified by a unique identification code.

The network nodes 11 are preferably provided with means for wireless data communication. These bodies may be of a conventional type and are not further described here. In more developed systems in accordance with the invention, the network nodes 11 can be provided with additional functions and a higher degree of independence. In the embodiment shown in Fig. 1, the central unit 16 is connected with wire to a network node 20 without wireless function, but within the scope of the invention, a network node 11 with wireless function can also be used for this purpose. The central unit 16 with associated peripheral equipment and the network node 20 are arranged in a first room 21 marked with a dashed line in Fig. 1.

Other components are arranged in a second room 22 and a third room 23. The second room 22 is in the example shown in turn divided into rum your rooms equipped with different combinations of network nodes and indicators.

The rooms are marked with dotted lines. All premises are included in the facility covered by the installation in accordance with the invention.

The network nodes 11 may be connected to the electrical distribution network 10 in various ways. In the simplest version, the network node is connected via a standard wall socket, or a lamp connector. Suitably, in such embodiments, the network node is mechanically attached to the socket to make removal and relocation more difficult. In environments with a risk of tampering, a fixed wire connection to the distribution network 10 is used. The wire connection can take place in a ceiling or in a wall. The central unit 16 stores information and the identity of the network node and where the network node is located. As a result, all communication that takes place through the network node can be located with high resolution in the building and rooms, and even in part of the rooms. Devices, which are connected via network nodes, can thereby be positioned. The network nodes 11 communicate continuously with the central unit. If the communication cannot be maintained, an alarm is given. The alarm can be initiated either by the network node or by the central unit 16, or a unit connected to it.

In a room 24, a typical installation in a hospital environment in accordance with the invention is made. A first network node 11 with wireless function is connected to the mains 10. A second network node 20 without wireless function connects a control panel 25 to the mains 10. The control panel 25 is connected to various alarm units on or at a patient in the room 24. A handheld alarm transmitter 13 with different buttons 26 for different alarm levels is available to the patient, who can call for help from staff.

A patient-operated alarm unit 27 for sensing, for example, pulse and other cardiac activity, automatically gives an alarm in the event of a form of fault condition.

In the embodiment shown, the alarm transmitter 13 is wirelessly connected to a local network node 11, while the alarm unit 27 is wirelessly connected to the control panel 25, which in turn is connected to the mains via a network node 20, without wireless function. In other embodiments, the respective arm unit is connected to the mains in a suitable manner by wire or wirelessly. The monitoring unit 12 and the control panel 25 are designed for wired or wireless bidirectional communication and can in one embodiment function as a sub / slave exchange for the central unit 16.

The alarm transmitter 13 and the alarm unit 27, respectively, are assigned a specific alarm identity. Other devices used in the system in accordance with the invention may be assigned a unique technical identity accordingly. Information about the identity is attached when sending alarms and other data, so that correct association to a carrier of the alarm transmitter 13 or the alarm unit can be made in the central unit or other corresponding unit. The alarm transmitter 13 and the alarm unit 27, respectively, can be provided with means for measuring horizontal and vertical position as well as with an accelerometer to be able to indicate, for example, that the carrier is falling.

In the room 24, or in direct connection thereto, an alarm indicator 15 is arranged. The alarm indicator 15 is also wirelessly connected to a network node 11 and thereby connected to the mains and other units. The alarm indicator 15 can be assembled or otherwise connected by wire to the network node 11. In the event of an alarm condition in the room 24, the alarm indicator 15 is activated, so that personnel outside the room 24, for example in a corridor, pay attention - indicates that an alarm has been generated and in which room this has taken place. The alarm indicator 15 can be activated either by the equipment in the room 24, for example the control panel or the hand-held alarm transmitter 13, or via the central unit 16, which is given information about the alarm condition via the mains. Alarms can also be sent to personal handsets 14, or receiver communicators, for example in the form of a PDA 28, a so-called PDA (Personal Digital Assistant), pager or a mobile telephone. A well-developed handset or PDA can act as a personal control panel in the system. It also includes memory means for storing vital data for the patients for whom the wearer of the handset is responsible. Via position determination, the handset can lead responsible personnel to the desired position.

The receiver communicator can also be of simpler design, e.g. in the form of a minicall unit 29, or similar unit. In a suitable embodiment, the receiver communicator is provided with a display for reading alarms and other information as well as with function buttons for confirming received information and for being able to send at least simple messages to the central unit 16 and to other units.

The central unit 16 is important for the operation of the system in accordance with the invention. The central unit stores information about staff, technology and the desired patient-specific information regarding illness, status and medicines. Each hospitalized patient is associated with a specific alarm unit 26 and / or a specific alarm transmitter 13, whereby alarm signals, which are transmitted via a network node 11 and the electrical distribution network to the central unit 16, are automatically connected to the correct patient. Alarming and other communication from and to the patient takes place via a network node 11, whereby the current geographical location of the alarm unit, or other unit that communicates, is known.

Within the scope of the invention, the central unit 16 can be divided into a number of separate computer units. The computer units can be arranged in different spaces and different buildings. Communication between the computer units can take place via the electrical distribution network in the same way as described above for other technical equipment, but also via conventional communication channels, such as wired data network and wireless data communication.

Conventional communication technology is suitably used, if the computer units are arranged in different plants with separate electrical distribution networks.

In the storage unit 17 connected to the central unit 16, the data required for real-time handling of various applications within the scope of the invention are stored. Settings, messages and other activities are saved to create traceability. Conveniently, the storage unit 17 fl includes superficial storage media for backup and long-term storage. information can also be moved or copied to patients' other medical records after the end of the hosting session.

The wireless communication between the network nodes 11 and handheld alarm devices and other mobile devices takes place at the available carrier frequency, e.g. 868 MHz, and preferably using available protocols and communication systems. To increase safety regarding crosstalk between storeys in a building, the simultaneous use of several carrier frequencies can be used. This also makes it possible to continuously determine the current position of alarm transmitters 13, patient-operated alarm units 26, hand-held units 14 and other wirelessly connected units. A corresponding division into several carrier frequencies can also be made to separate different groups on one and the same floor.

The system in accordance with the invention offers möjligheter your possibilities for positioning units. In addition to the possibilities described above, mobile units may be provided with special means for positioning, for example means for positioning by means of gyro. A gyro position determining means can continuously emit signals which indicate the position of the mobile unit.

The measurement principle is based on inertial navigation with measurement of the movement of an object. Gyro positioning can be used to advantage in configurations with sparsely arranged network nodes.

Positioning can also be facilitated by limiting the transmitting power of mobile devices and thus the range. The transmitter power can be set so that the communication between mobile units and network nodes is delimited to adjustable distances, for example within a room or a floor.

Simpler mobile units, such as the alarm transmitter 13, handheld units 14 and minicall units 29, usually transmit only a few types of signals to one or possibly a few receivers, and otherwise communicate information about one's own position or the like. The alarm transmitters 13 can be provided with indicators, e.g. lamps or LEDs, to provide the user with information that alarms have been received and that summoned personnel are on their way. In some applications, the alarm transmitters 13 and other mobile units are provided with a display to enable the transmission of more complex information, e.g. instructions on medication or directions to lead a patient to the desired location. The hand units 14 and the mini call units 29 intended for different categories of personnel can also be provided with a display and a keypad to enable different forms of communication.

The possibility of communication that arises through the use of the electrical distribution network as a communication medium can also be used for more conventional information transmission. This is indicated in Fig. 1 by a conventional computer 34 and intercoms 35. The computer 34 and the intercoms 35 are provided with either built-in or external network nodes and communicate with other corresponding units via the network nodes and the electrical distribution network. The computer 34 and the intercoms 35 can be designed for both wireless and wired communication via the network nodes.

An installation carried out in accordance with the invention may also include devices for collecting information and / or controlling common mechanical equipment. Fig. 1 illustrates this by an electric motor 37, which is connected to the central unit 16 via a network node 20 without wireless function. The electric motor 37 can be part of an elevator, a fl genuine or some form of ventilation equipment.

The part of an installation according to the invention shown in Fig. 2 comprises an alarm indicator 15 and a road indicator 30 mounted in a corridor roof. When an alarm has been activated by a network node 11 in a room, the central the unit, by knowing the location of the network node 11 and the positions of the staff, indicate the way to the room and the network node. This can be done by using indicators, e.g. lamps, LEDs or Greek displays 31, on road indicators 30 along a suitable travel path for certain personnel are activated. An alarm indicator 15 arranged in connection with the room in which the alarm has been activated is also lit, as shown in Fig. 2.

The embodiment of a network node 11 shown in Fig. 3 is intended for mounting in a conventional wall socket as an ordinary plug. wall sockets and plugs occur in different designs in different countries and the network nodes 11 are adapted to current conditions. Two pins 32 project from one rear side of the network node and fit into corresponding openings in the wall socket.

In the embodiment shown, the network node 11 is intended to be fastened to a wall socket screwed into a wall. This is accomplished by making the network node with through holes 33 in a configuration corresponding to the configuration of the wall socket mounting screws (not shown). This design makes it possible to attach the network node 11 to and together with the wall socket. The network node also includes an antenna 34 in this embodiment. The antenna 34 is dimensioned for the frequency range used in the wireless communication between network nodes and mobile devices. In some designs, the antenna is built-in.

The versions of network nodes that are directly and permanently connected to the electrical distribution network are designed in a suitable way for this type of connection. It is also possible that electrical appliances used in the buildings covered by an installation in accordance with the invention are provided with a built-in network node. When connecting such a device to the electrical distribution network, the network node automatically becomes available for communication with other network nodes and with the central unit.

An example of a network node 38 built into an apparatus 39 is shown in FIG. The apparatus 39 may be a dialysis apparatus, a respirator, a monitoring monitor or any similar device, with or without medical function.

The network node 38 comprises a network module 40, which technically corresponds to a network node described above with electronics for transmitting data signals on an electrical distribution network. In Fig. 4, the network module 40 is connected to the distribution network 10. Via this connection, the current reconciliation of the apparatus 39 also takes place.

The built-in network node 38 also includes a data capture module 41 and a control module 42, which are connected to an electronics module 43 belonging to the device 39. In the data capture module 41, information regarding patient, healthcare personnel handling the device and technical values regarding the processing are entered and stored. the device is used in, alarm limits and current operating data of the device. The operating data stored can include chemical levels, battery voltage, operating times, temperatures and similar data. In this context, important data relate to any leakage currents in the protective earth line and any electrical connection with the patient.

In the event of a leakage current of a certain intensity, an alarm signal can be sent to the central unit 16, or another corresponding unit, via the built-in network node 38. Many devices used in healthcare, such as respirators and dialysis devices, cannot be switched off automatically in the event of a leak. leakage currents, as this could lead to danger to the patient's life.

The control module 42 handles certain functions of the device, such as logging in operating personnel, approving patient connection, medical remote control in order to be able to stop ongoing treatment and approve treatment with the fi glasses and similar special equipment. The control module 42 is also designed to retrieve various device settings, which are needed for current treatment with the device, and to change technical settings and calibrate devices in the device. Other functions of the control module 42 are in communication, for example to display the current status of the device and other information and to register control commands and transmit them to the electronics module 43.

The electronics module 43 essentially comprises functions of a conventional kind for controlling and monitoring the apparatus. Communication with external control and monitoring equipment, for example a central unit 16 takes place via the network module 40. The user and / or staff can use an input and output unit 44, which may for example comprise a display and a keypad, for controlling and monitoring the device in a more conventional way. The communication over the electrical distribution network takes place in several levels. The primary information carrier is one of the technologies on the market, PLC, ADSL or other equivalent. These techniques are the bearers of an alarm and control protocol adapted to the invention for exchanging information between the various functions in the system. The protocol is a dynamic protocol that adapts the amount of information to the currently optimal size. This means that each actual amount of information is preceded by start information and ends with a stop information. This takes place at different levels and applies to each individual information module and out to cover the entire protocol.

The protocol is made up of various information modules. There are modules for activity, identity, information key, security key, routine, patient information, personnel information, technical information, data and empty modules for future needs. For a very time-critical and acute alarm, the protocol contains few but vital amounts of information about activity (type of alarm) and identity about which patient, equipment, time and geography the alarm refers to, as well as its own unique info key. For the minimized amount of information, the central unit may determine the reception of the alarm and its further handling.

When both the time criteria and the data volumes are relatively high, the information module is provided with data with an info key that enables direct control of the information from the transmitter to the receiver. It can e.g. apply to the transmission of speech for rapid telephony, ECG or other current amount of information. When the time criteria are low and no other protocols require space in the network, the protocol can be made long and complete with all information modules and large volumes of information.

Below is a brief description of the various information modules.

Activity indicates the type of alarm to which the protocol refers, such as emergency alarms, service alarms, attention alarms, etc. as well as variants of the country type heart, toilet visits, soon run out of paper and so on. 10 15 20 535 835 14 Identity indicates sender, default recipient, geographical location, time, technical ID and the like. lnfo key creates an identity on the data set and the information process that is created.

Security key locks and encrypts the protocol. The security key also acts as a certificate to obtain permission for the protocol to pass firewalls and enter the various system units, as well as permission to change stored information. The finesse of a security key is that all executable code must have an approved key to get time with a processor that will execute the code. This security thinking permeates all system components that use computer programs for their function, and includes both technical units and, if necessary, individual or all protocols.

Routine indicates how the information is to be handled and what is expected of the recipient.

Patient information is a concentrated vital information about the patient.

Personnel information is a concentrated vital information about the staff.

Technical information is a concentrated vital information about the technology and the information content.

Data is the actual amount of data when it is greater than what is included in the above.

Development is a space that may be needed for future needs.

Claims (16)

10 15 20 25 30 535 835 15 PATENT REQUIREMENTS A method of bidirectional communication over an electrical distribution network (10) in an installation, in which data signals are transmitted via network nodes connected to the electrical distribution network, characterized in that information about the physical location of the network nodes (11) and one for each network node ( 11) unique identity is stored in a storage unit (17) of a central unit (16), that the network nodes (1 1) are wirelessly connected to mobile units (13; 14; 15; 27; 28; 29), that communication between mobile units (13; 14; 15; 27; 28; 29) are performed via network nodes (1 1) and the electrical distribution network (10), to be lamely activated by a first mobile unit in the form of a alarm transmitter (13), sends information about an activated alarm to a second mobile unit in the form of a handset (14; 28) and that information communicated between mobile units (13; 14; 15; 27; 28; 29) is registered and stored in the central unit (16). A method according to claim 1, wherein the position of mobile units (13; 14; 15; 27; 28; 29) is determined by the pre-stored physical location of the network node through which the mobile unit communicates. A method according to claim 1, wherein network nodes (11) are grouped by allocating different carrier frequencies or other corresponding channel division. Method according to claim 1, wherein the transmitter power of mobile devices (13; 14; 15; 27; 28; 29) is limited, so that communication between mobile devices and network nodes is delimited to adjustable distances. Method according to claim 1, wherein data signals transmitted in the electrical distribution network are attenuated at boundaries of the plant. 10 15 20 25 30 535 835 16 A method according to claim 1, wherein signals indicating the position of the mobile units (13; 14; 15; 27; 28; 29) are continuously transmitted to the central unit (16). Device for bidirectional communication over electrical distribution network (10). a plurality of network nodes (11; 20) being connected to the electrical distribution network (10), characterized in that the network nodes (11; 20) are connected to a central unit (16), that the central unit (16) is designed to store information about the physical location of the network nodes (11) and an identity unique to each network node (11), that network nodes (11) are wirelessly connected to mobile units (13; 14; 15; 27; 28; 29), that a first mobile unit is made as an alarm transmitter (13) with a button for activating an alarm and is connected to the central unit (16) via a network node (11), that a second mobile unit is designed as a handset (14; 28) and is connected to the central unit (16). ) via a network node (11), that the central unit is designed to transmit alarm information from the alarm transmitter (13) to the handset (14; 28) and comprises a storage unit for recording and storing such communication information which is exchanged between mobile units. (13; 14; 15; 27; 28; 29). A device according to claim 7, wherein a patient-mounted alarm unit (27) is wirelessly connected to a network node (11). Device according to claim 7, wherein a number of alarm indicators (15) are connected to the central unit (16) via the electrical distribution network (10). Device according to claim 7, wherein a network node (20) without wireless function is operatively connected to an electrical machine (37). 10 15 20 535 835 17 Device according to claim 7, wherein network nodes (11; 20) are mechanically connected to electrical wall sockets. Device according to claim 7, wherein mobile units (13; 14; 15; 27; 28; 29) are provided with an indicator and display. Device according to claim 7, wherein alarm transmitters (13) are provided with an indicator to confirm that alarms have been sent and received. Device according to claim 7, wherein a plurality of road indicators (30) are connected to the central unit (16) via the electrical distribution network (10), so that a route for staff to a land position can be indicated by activating road indicators (30) along the path of movement. Device according to claim 7, wherein mobile units (13; 14; 15; 27; 28; 29) are provided with a gyro unit for continuous positioning of the unit. A device according to claim 7, wherein hand-held handsets (14; 28; 29) are provided with memory means with patient data.