-1~ OBJECT PROXIMITY WARNING SYSTEM AND METHOD Field of the Invention 5 The invention relates to a system for generating a proximity warning and a method for generating a proximity warning, for issuing proximity warnings. Background of the Invention 10 Surface mines and similar sites or areas are generally operated by means of a large number of vehicles, some of which may be exceedingly large and difficult to control and have very limited visibility for the operator. 15 It has been proposed to use GNSS-devices (GNSS = global navigation satellite system, such as GPS) on board of the vehicles and other objects, such as cranes, to generate proximity warnings in order to reduce the risk of collisions 20 between vehicles. Such a system is e.g. described in WO 2004/047047. The system is based on devices mounted to the objects. Each device comprises a GNSS receiver, a control unit deriving positional data using the signal of the GNSS receiver, a radio circuit for wireless exchange of the 25 positional data with the other devices, and an output device for outputting proximity warnings. Another approach based on GNNS receivers is disclosed in the International Application No. PCT/CH2009/000200 incorporated 30 herein by reference. Other approaches for extra-large vehicles are introduced in "Avoiding accidents with mining vehicles", retrieved and -2 accessed from/on the Internet at http: //www. flir. com/uploadedFiles/Eurasia/MMC/Appl Storie s/AS_0020_EN.pdf on February 2, 2010. Accordingly, some of 5 the vehicles are equipped with an 8m radar system which warns the driver when something is in his path. In addition to the radar system GPS traffic alert systems can be installed which warns the driver of any possible accidents. 10 It is generally desirable to overcome or ameliorate one or more of the above described difficulties, or to at least provide a useful alternative. Summary of the Invention 15 According to the present invention, there is provided a system for generating a proximity warning, comprising a first monitoring device comprising a receiver for a radio based positioning system for determining the position 20 of an object the first monitoring device is mounted to, a second monitoring device for measuring the distance to another object, and a common output device for issuing a first proximity warning in dependence of positional data supplied by said 25 first monitoring device, and for issuing a second proximity warning in dependence of distance data supplied by said second, monitoring device, wherein said first proximity warning is different to said second proximity warning. 30 According to the present invention, there is also provided a method for generating a proximity warning, comprising: -2A determining the position of an object to which a first monitoring device with a receiver for a radio based positioning system is mounted to, measuring the distance to another object by means of a 5 second monitoring device, issuing a first proximity warning by a common output device in dependence of the determined position, issuing a second proximity warning by said common output device in dependence of said measured distance, 10 wherein said first proximity warning is different to said second proximity warning. Preferred embodiments of the invention seek to provide an improved warning mechanism. 15 According to a first preferred embody. tent of the present invention, a system is provided for generating a proximity warning. The system comprises a first monitoring device comprising a receiver for a radio based positioning system 20 for determining the position of an object the first monitoring device is mounted to. The system further comprises a second monitoring device - preferably mounted to the same object as the first monitoring device - for measuring the distance to another object, preferably in the 25 vicinity of the present object. A common output device is provided for issuing a first proximity warning in dependence of positional data supplied by the first monitoring device, and for issuing a second proximity warning in dependence of distance data supplied by the second monitoring device. 30 Consequently, the common output device is assigned to both monitoring devices. An "output device" in the context of the -213 present invention is a device for issuing warnings comprising one or more output elements such as visual elements, acoustic elements, or others. Preferably, the output device comprises an interface to a control unit, 5 which processes the outputs of both monitoring devices thereby triggering the warnings to be issued by the output elements of the output device. Such interface my be at least a unidirectional interface, or WO 2011/130861 PCT/CH2010/000106 3 may be a bi-directional interface, and may, for example, be implemented as a bus system. The control unit may be arranged remote to the output device or may be integrated into the output device. The control unit itself may com s prise an interface to the two or more monitoring devices which feed their signals into the control unit common to all monitoring devices. Preferably, the control unit may be enabled for evaluating the signals from the multiple monitoring devices in combination. The control unit may 10 be arranged in a common housing with one or more of the output elements. In such scenario, the control unit of the output device receives the signals from the monitor ing devices directly by means of suitable interfaces. Again, in such a scenario, the control unit may be en 15 abled for evaluating the signals from the multiple moni toring devices in combination. By providing a common output device to the monitoring devices, a first step of integrating monitor ing devices working along different monitoring principles 20 into a single monitoring system is achieved. Irrespective of the signals from the monitoring devices and/or infor mation in the signals being combined, the output device is embodied as a component in which the output elements are combined. This also holds if the control unit for 25 evaluating the signals from the monitoring devices is em bodied as part of the output device itself and controls the output elements of the output device. In a preferred embodiment, the first prox imity warning is different to the second proximity warn 30 ing. This in particular includes that a physical appear ance of the first warning differs from a physical appear ance of the second warning. Hence, the person in charge is in a position to derive from which kind of monitoring device the warning is basically triggered. For the reason 35 that the two monitoring devices rely on different measur ing principles, they inherently provide different kind of information, which may bring the person in charge in a WO 2011/130861 PCT/CH2010/000106 4 position to better react to potentially dangerous situa tions. While in an embodiment a GNSS based receiver al lows for determining the position of the object the GNSS receiver is mounted to, and, preferably in combination s with positional information delivered by GNSS based re ceivers mounted on other objects, allows for. determining the distance to such other objects and preferably the di rection, it is known that such monitoring device needs to rely on other objects being tagged with a GNSS based re 10 ceiver, too. This also holds for an embodiment where the current position of the present object determined by means of the GNSS receiver is mapped to a map electroni cally stored, such map showing possible immobile (or tem porarily immobile) obstacles in the vicinity. On the is other hand, the second monitoring device may detect proximate objects in a different range, e.g near-by ob jects, e.g. within the range of 10 meters, which do not need to be tagged. For example, radar, lidar, or ultra sonic sensing can provide such distance information with 20 respect to near-by and untagged objects. Whenever such second monitoring device raises a warning, such warning provides additional information to the person in charge based on the knowledge of the different sensing princi ples. This is why it may be advantageous for any operator 25 of e.g. large vehicles in a mine to be in a position to distinguish a warning stemming from a GNSS based prox imity measurement system to a warning from a non-GNSS distance measurement system, preferably based on runtime evaluation. In case, only the second proximity warning is 30 issued but not the first, the operator can derive that there potentially is an object close by not being equipped with a GNSS based receiver such that it may be necessary to stop immediately. On the other hand, in case only the GNSS based receiver indicates a - tagged - ob 35 ject but the second monitoring device does not - provided both devices look into the same direction - the operator can derive that the situation may not be of immediate danger (yet) Other preferred embodiments of the present invention are 5 stipulated in the dependent claims. Such embodiments refer to the appearances which enable the warnings to be differentiated, or refer to a possible cross-relationship between warnings and monitoring units. Other dependent claims refer to the various embodiments of the second 10 monitoring device. According to another preferred embodiment of the present invention, a method is provided for generating a proximity warning. The method comprises determining the position of an 15 object to which a first monitoring device with a receiver for a radio based positioning system is mounted to, measuring the distance to another object by means of a second monitoring device, issuing a first proximity warning in dependence of the determined position, and issuing a 20 second proximity warning in dependence of said measured distance, wherein said first proximity warning and said second proximity warning are issued by a common output device. 25 In another preferred embodiment of the present invention, a method is provided directed to deploying the disclosed system to an entire area such as a mining site. A plurality of first monitoring devices are provided, wherein at least some of said first monitoring devices are installed on 30 objects operating in said area, wherein at least part of said first monitoring devices comprise a receiver for a radio based positioning system and a radio circuit, and at -6 least one second monitoring device installed on one of the objects comprising at least one of said first monitoring devices, wherein said second monitoring device measures the distance to another object. In such environment, by means of 5 said first monitoring device, a first device status dataset depending on a position of said first monitoring device is generated and emitted through the radio circuit of said first monitoring device. A de-vice status datasets from monitoring devices installed on other objects is received by 10 said first monitoring device. From said first device status dataset and at least one of the received device status datasets a distance and an orientation between the present object to the other object is determined such that based on the determined distance a first proximity warning may be 15 issued. A second proximity warning may be issued in dependence of a distance measured by the second monitoring device. Again, first and second proximity warnings are issued by a common output device. 20 Consequently, a system and a method are disclosed for generating a proximity warning. Based on two different sensing principles proximate objects can be detected by respective monitoring devices. The warning system is designed such that each monitoring device issues a warning 25 via a common output device being fed by signals originating from the monitoring devices. The described embodiments similarly pertain to the system, the method, and the apparatus. Synergetic effects may arise 30 from different combinations of the embodiments although they might not be described in detail.
-7 Further on it shall be noted that all embodiments of the present invention concerning a method might be carried out with the order of the steps as described, nevertheless this has not to be the only essential order of the steps of the 5 method all different orders of orders and combinations of the method steps are herewith described. Brief Description of the Drawings 10 Preferred embodiments of the present invention are hereafter described, by way of non-limiting example only, with reference to the accompanying drawings, in which: Figure 1 shows a schematic representation of a site. 15 Figure 2 is a block diagram of a system according to an embodiment of the present invention. Figure 3 is a schematic top view on a vehicle equipped with four second monitoring devices according to an embodiment of the present invention. 20 Figure 4 illustrates an optical display according to an embodiment of the present invention. Detailed Description of Preferred Embodiments of the Invention 25 Similar or relating components in the several figures are provided with the same reference numerals. A "movable object" is any object that can change and is 30 expected to change its position and/or orientation or configuration in space. It may e.g. be a truck or any other vehicle that moves from place to place and changes its orientation in respect to the general north- south direction, -7A e~g. by steering, or it may be an object positioned at a fixed location but able to rotate about its axis or to change its physical configuration, e.g. by extending an arm, in such a manner that the volume of safety space attributed 5 to it varies in significant manner. The term GNSS stands for "Global Navigation Satellite System" and encompasses all satellite based 10 navigation systems, including GPS and Galileo. The term "radio based positioning system" stands for a GNSS or for any other type of positioning system based on radio signals, such as a pseudolite system, a WiFi based Real Time 15 Location System (RTLS) , etc.
WO 2011/130861 PCT/CH2010/000106 8 Fig. 1 schematically depicts a site 1, such as a surface mine, to be monitored by the present system. The figure primarily shows the components relevant in the context of the present invention. Typically, such a site s covers a large area, in the case of a surface mine e.g. in the range of square kilometers, with a network of roads 2 and other traffic ways, such as rails 3. A plu rality of objects is present in the mine, such as: - Large vehicles, such as haul trucks 4a, 10 cranes 4b or diggers 4c. Vehicles of this type may easily weigh several 100 tons, and they are generally difficult to control, have very large breaking distances, and a large number of blind spots that the driver is unable to visually monitor without monitoring aids, such as e.g. is cameras. - Medium sized vehicles 5, such as regular trucks. These vehicles are easier to control, but they still have several blind spots and require a skilled driver. 20 - Small vehicles 6. Typically, vehicles of this type weigh 3 tons or less. They comprise passenger vehicles and small lorries. - Trains 7. A further type of object within the mine is 25 comprised of stationary obstacles, such as temporary or permanent buildings 9, open pits, boulders, non-movable excavators, stationary cranes, deposits, etc. The risk of accidents in such an environment is high. In particular, the large sized vehicles can eas 30 ily collide with other vehicles, or obstacles. For this reason, the mine 1 is equipped with a monitoring equipment that allows to generate proximity warnings for the personnel of the site, thereby reducing the risk of collisions and accidents. 35 Basically, the each of the objects comprises at least one first monitoring device 12 which includes a radio based positioning system interacting with satel- WO 2011/130861 PCT/CH2010/000106 9 lites 16. These devices 12 communicate in wireless man ner, in particular by radio signals. The first monitoring devices 12 are e.g. in stalled on the objects 4 - 7, and 9. 5 An exemplary system according to an embodi ment of the present invention is shown in a block diagram in Fig. 2. The system comprises a control unit 14, such as a microprocessor system, which controls the operations of the system, and in particular controls an output de 10 vice 19. The system 15 further comprises a first moni toring device 15 in form of a GNSS receiver. Although it is called a GNSS receiver in the following, it can also be a receiver interoperating with any other radio based is positioning system for determining its position. The pre sent invention can be used on various types of radio based positioning systems. The system 15 further comprises a second monitoring device 40. The second monitoring device 40 is 20 a radar device for determining the distance to a near by object, such as within the range of e.g. 10 - 20 meters, by means of the radio detection and ranging concept as known to those skilled in the art. The system 15 further comprises a radio 25 transceiver or circuit 17 for exchanging data with other parts of the monitoring apparatus, e.g. with other sys tems 12. A control unit 14 accesses a memory 18 that comprises programs as well as various parameters, such as 30 a unique identifier of the monitoring devices 12 and 40. The output device 19 advantageously comprises output elements such an optical display 20 using LED's, LCD's, etc. as well as an acoustic signal source 21, such as a beeper. In addition, such output device 19 may com 3s prise another speaker via which electronically generated voice messages may be issued as warnings. Proximity warn ings can, e.g. be issued by the optical display 20 that WO 2011/130861 PCT/CH2010/000106 10 can be observed by the user and/or an acoustic signal. In addition, the acoustic signal source 21 can generate voice data and/or other types of sound. The control unit 14 may also be part of the output device 19. Output de s vice 19 including output elements 20, 21 and control unit 14 in an embodiment can be arranged in a common housing. In another embodiment, only the output elements are ar ranged in a common housing, and the control unit may be located remotely. The control unit 14 may evaluate the 10 data received from the monitoring devices 12 and 40 and may generate signals supplied to the output device 19 for generate or triggering the warnings. In another embodi ment, the common output device may be embodied such that at least one of the output elements is designed for issu 15 ing both, the first and the second proximity warning. The primary purpose of the system 15 is to generate proximity warnings in case that there is a dan ger of collision. As mentioned in the introduction, this is achieved by receiving at least positional signals 20 through GNSS receiver and exchanging data derived there from with other systems in order to calculate relative positions and probabilities for collisions, and by re ceiving distance signals through the radar device. Any data supplied by the monitoring devices in general, or 25 subject to specific thresholds, may be logged in a log 60. The log 60 may also be integral part of the memory 18. In the log, different data may be recorded: It may be such that the positional data and/or the distance data may be recorded continuously or triggered by one of the 30 data fulfilling a criterion such as the distance being less than a threshold which may indicated an upcoming crash. And/or, the signals generated by the control unit 14 for triggering the warnings may be recorded. Any log may help in later verifying why a crash may have hap 3s pened, and may verify the proper operation of the system. In addition, in a preferred embodiment, a de tection device for detecting fatigue of the operator / WO 2011/130861 PCT/CH2010/000106 11 driver may be provided and integrated into the overall system such that the first warning and / or the second proximity warning may depend on a signal from such fa tigue detection device. In another embodiment, such fa 5 tigue detection device may be in a position to issue a separate warning itself. The operation of the first monitoring devices can be basically as in conventional systems of this type, such as e.g. described in WO 2004/047047 and need not be 10 described in the very detail herein. In short, in a sim ple approach, each device obtains positional data derived from a signal from GNSS receiver. This positional data allows determining the position of the device and is stored in a "device status dataset". The device status 15 dataset also contains a unique identifier (i.e. an iden tifier unique to each of the first monitoring devices 12 used on the same site). The device status dataset is emitted as a radio signal through transceiver 17. At the same time, the device receives the corresponding signals 20 from neighboring devices and, for each such neighboring device, it calculates the relative distance d by sub tracting its own coordinates from those of the neighbor ing device. A proximity warning triggered by the posi 25 tional information - which for the first monitoring de vice includes distance information with respect to an other object, too for the reason that the distance is de termined by differences in the position of the two ob jects in question - can be generated by means of various 30 algorithms. Examples of such algorithms are described in the following. In a very simple approach, it can be tested if the absolute value of the relative distance d is below a given threshold. If yes, a proximity warning will be issued. This corresponds to the assumption that a 35 circular volume in space is reserved for each object. The radius of the circular volume attributed to an object can e.g. be encoded in its device status dataset. A more ac- WO 2011/130861 PCT/CH2010/000106 12 curate algorithm can e.g. take into account not only the relative position, but also the driving velocities and directions of the vehicles. An improvement of the predic tion of collisions can be achieved by storing data in 5 dicative of the size and/or shape of the vehicle that a monitoring device is mounted to. This is especially true for large vehicles, which may have non-negligible dimen sions. In a most simple embodiment, a vehicle can be mod eled to have the same size in all directions, thereby de 10 fining a circle/sphere "covered" by the vehicle. If these circles of spheres of two vehicles are predicted to in tersect in the near future, a proximity warning can be issued. Instead of modeling an object or vehicle by a simple circle or sphere, a more refined modeling and 15 therefore proximity prediction can be achieved by storing the shape (i.e. the bounds) of the vehicle in the dataset or by determining the same dynamically as in the embodi ments described below. In addition, not only the shape of the vehicle, but also the position of the GNSS-receiver 20 (or its antenna) in respect to this shape or bounds can be stored in memory 18. The second monitoring device 40 - which is not shown in Figure 1 but is assumed to be present on many of the vehicles for monitoring the vicinity in at 25 least one direction - may issue e.g. via a control unit for evaluating the measured distances a warning signal which triggers the output device to issue the second proximity warning when the distance is less than a threshold, e.g. less than 5 meters. Subject to the meas 30 uring principle used and the range of interest to be scanned the maximum range within which another object can be detected, e.g. in a runtime measurement measuring the time between issuance of a signal, be it a radio signal, a light signal - in particular a laser signal-, or a 3s sonic signal - in particular an ultrasonic signal -, and the receipt of the signal reflected at the remote object, may be preferably less than twenty meters. The advantage WO 2011/130861 PCT/CH2010/000106 13 of such monitoring devices is that in contrast to the GNSS based devices the remote object needs not to be tagged or equipped with any detection unit. This is why such a monitoring device ideally complements the GNSS s based monitoring device. Preferably, the second monitor ing device is based one of radar, lidar and sonic tech nology for determining the distance to a near-by object. Alternatively*, or in addition to evaluating the distance to other objects by means of these objects 10 having GNSS receivers installed, too, the corresponding positional information of these objects being transmitted to the present object, and a distance value being derived from the positional information of the present and the other object, the positional information of the present 15 object can also be compared to positional information of preferably stationary objects electronically stored in a map 50 as shown in Figure 2. The map 50 may include in formation on stationary objects of a site, and the con trol unit 14 may be designed for determining a distance 20 between the current position of the present object from e.g. stationary objects derived from such map 50. The output device 19 may be designed for issuing the first proximity warning when such distance is less than a threshold. 25 When it comes to the arrangement of the sec ond monitoring device(s) at an object, it is advantageous to address each side of the object with a second monitor ing device. In this sense, Figure 3 illustrates a sche matic top view on a vehicle 6 equipped with four second 30 monitoring devices 40 in form of lidar devices, one lo cated at each side of the vehicle 6. Alternatively, the lidar devices 40 can be located at the edges of the vehi cle 6. Both arrangements are beneficial for covering a large area in the vicinity of the mobile object for prox 3s imity and/or collision detection purposes. In such arrangement, the warnings based on information delivered by one of the second monitoring de- WO 2011/130861 PCT/CH2010/000106 14 vices 40 may preferably allow for an indication which one of the several second monitoring devices 40 has detected an object near-by resulting in the warning. Preferably, the warnings issued by the several second monitoring de 5 vices 40 can be distinguished. For example, the warning assigned to the second monitoring devices 40 is an opti cal warning issued by an optical display 20 in form of multiple LEDs (light emitting diode), as shown in Figure 4. An output device - understood as combination of sev 10 eral output elements be it visual or acoustic including speech based warning elements - may include the optical display 20 including four LEDs 200, 201, 202, 203 ar ranged in the corners of a virtual square or on a virtual ring by this indicating a direction, for example in rela is tion to a forward moving direction of the vehicle. When ever the radar device to the right hand side in Figure 3 causes issuing a second warning the corresponding LED 201 to the right hand side of the optical display 20 is flashing. Whenever the radar device to the left hand in 20 Figure 3 causes issuing a second warning the correspond ing LED 203 is flashing, etc. By this the operator is aware to which side of the vehicle another object is close by. In addition to the four LEDs 200 - 203 repre senting warnings triggered by the second monitoring-de 25 vices 40, the first monitoring device 12 is assigned two more rings /squares of LEDs 300 - 303 and 400-403 in the optical display 20. Provided the first monitoring device 12 is capable for identifying other tagged objects not only with respect to the distance but also with respect 30 to the direction, the middle ring of LEDs 300-303 is as signed to the first monitoring device detecting a tagged object in the mid-range, and the outer ring of LEDs 400 403 may be assigned to an object detected in a far range by the first monitoring device 12. Overall, such visual 3s warning system may comprise three LEDs per direction, two of which are assigned / connected to the first monitoring device 12, the last one being assigned to the second WO 2011/130861 PCT/CH2010/000106 15 monitoring device 40 such that the operator always is in a position to determine which monitoring device 12, 40 is issuing a warning. In addition, each ring of LEDs may have a different colour than another ring of LEDs. For s example, the LEDs 200 - 203 of the inner ring may flash in a warning colour such as red, while the LEDs 400 - 403 of the outer ring may flash in a colour different to red, such as green, indicating that no immediate action may be required, while the colour of the LEDs 300 - 303 in the 10 middle ring may be yellow for example, indicating medium risk. Instead, or in addition, the LEDs may flash with different frequencies, the higher the risk, the higher the frequency. Instead of the LEDs, there may be provided other visual elements, such as warning symbols, text, or 15 other signs, arranged as individual elements, or, com bined, on a display. Also, the position of the first and the sec ond visual proximity warnings may be differently ar ranged, e.g. on a common flat panel display. 20 In general, the first and the second prox imity warnings are preferably different in their appear ance for better enabling an operator to immediately as sess the risk associated. This not only holds for the warnings being embodied as visual warning. Instead the 25 first proximity warning may be a visual warning, whereas the second proximity warning may include an acoustic warning in addition to a visual warning, or an acoustic warning exclusively. An acoustic warning may be a beep or any other sound drawing attention to the monitoring sys 30 tem. In another embodiment, it may even be that both proximity warnings include acoustic warnings. Again, such acoustic warnings then differ, for example, in their vol ume, their frequency, their beeping frequency, their sound, etc. 35 According to another aspect of the present invention, there is provided that an appearance of the first proximity warning is variable subject to said loca- WO 2011/130861 PCT/CH2010/000106 16 tion/distance data. Such embodiment is already described with respect to the above LED display. The same may apply to an appearance of second proximity warnings which may be variable subject to said distance data. In an optical s display such as the one above, there may be provided an other ring of four LEDs arranged as a very inner ring which for example flashes at high frequency whenever an object detected by the second monitoring device is, for example, closer than two meters from the object holding 10 the first and the second monitoring devices 12, 40. According to another preferred embodiment, the second and/or first proximity warning may be modified in its appearance subject to the positional data supplied by said first monitoring device. 15 Similar to the above, said first and/or sec ond proximity warning can also be modified in its appear ance subject to said distance data supplied by said sec ond monitoring device. In another embodiment, the second proximity 20 warning is modified in its appearance subject to previous distance data. For example, in a scenario, where a digger is digging close to a wall which most often is not equipped with the first kind of a monitoring device, the second monitoring device will cause issuance of warnings 25 each time the digger approaches the wall, although the operator is already aware of this obstacle. In order not to distract the operator by ongoing warnings, the system may be embodied such that whenever the distance to an ob ject frequently appears within a certain time period, it 30 can safely be assumed that the operator is aware of such obstacle such that the second warning is suppressed or modified such that its intensity decreases with each new approach. Such logic in particular can be combined with the positional information received from the first moni 35 toring device: Whenever the position of the digger re mains in about the same area and the above approach sce nario occurs, it can even more safely be assumed that the -17 obstacle is a permanent one being noticed by the operator already. Such concept may also apply to a modification of the first 5 warning, e.g. whenever a huge building is equipped with a GNSS based receiver, and a vehicle is being run in an area close to such building, the first proximity warning may be modified in its appearance subject to previous positional data allowing for an interpretation that the vehicle 10 currently is operating near and such building and the operator is aware of this. In general, such modification of a proximity warning may, e.g. include a complete suppression of the warning, or, in 15 case of an acoustic warning include one of a decrease and an increase in at least one of the volume and the alternating frequency and the frequency spectrum of said respective acoustic warning, or in case of a visual warning include one of a decrease and an increase in one at least one of the 20 intensity, the color, the flashing frequency, the representation of warning symbols, the position on the output device, and the appearance of said respective visual warning. 25 While there are shown and described presently preferred embodiments of the invention, it is to be distinctly understood that the invention is not limited thereto but may be otherwise variously embodied and practiced within the scope of the following claims. 30 Throughout this specification and the claims which follow, unless the context requires otherwise, the word "comprise", -18 and variations such as "comprises" and "comprising", will be understood to imply the inclusion of a stated integer or step or group of integers or steps but not the exclusion of any other integer or step or group of integers or steps. 5 The reference in this specification to any prior publication (or information derived from it) , or to any matter which is known, is not, and should not be taken as an acknowledgment or admission or any form of suggestion that that prior 10 publication (or information derived from it) or known matter forms part of the common general knowledge in the field of endeavour to which this specification relates,