• 专利附录
  • 专利说明
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    • 专利摘要:

    公开号:AT510385A2
    申请号:T0151210
    申请日:2010-09-13
    公开日:2012-03-15
    发明作者:Arne Dipl Ing Dr Sieber
    申请人:Arne Dipl Ing Dr Sieber;
    IPC主号:
    专利说明:

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    Inert gas bubble formation in the body - the so-called decompression sickness (or Chaisson disease, "bends"). John Scott Haldane and Robert D. Workman have for the first time described the inert gas uptake and experimentally / statistically given maximum allowable inert gas pressures that the human body can tolerate without a decompression accident "bends". to suffer. Albert. Based on this, A. Bühlmann developed the ZH-L16 algorithm, which describes the inert gas uptake in 16 hypothetical tissues with different saturation half-lives and different maximum inert gas pressures. Are the inert gas pressures in the tissues below > r a certain value, and thus the inert gas pressure below a certain maximum value, a return to the water surface is directly possible. Otherwise, during the ascent, so-called decompression tops must be maintained, in which inert gas is exhaled and thus the inert gas pressure in the tissues sinks to a safe level before the ascent continues. At the beginning of scuba diving instruments were used as instruments depth gauge and clock. Dive and climb to the surface were planned with Dek impression tables. These usually specify the maximum no-stop time (which indicates the maximum time that can be kept to a certain depth and then return to the surface without stops) and, if the no-stop time is exceeded, the decompression stops (each time and depth) , In particular, if a dive is not performed at a constant depth (multilevel dives are referred to), it is difficult to calculate and plan using tables. Modern dive computers have a minimum of a display, a Dmcksensor, an integrated timer or a clock and a computing unit. The dive computer continuously measures time and depth during the dive and uses this data to simulate the inert gas uptake in the body in the different tissues using a decompression model and then calculates the remaining idle time or indications, at which depth and for how long decompression stops must be complied with. Other dive computers also consider physiological parameters such as the heart rate (EP1S7S654A1) in the implemented models. Other patents describing dive computers are: US6304382B2, DE102007047133Al, DE102007047144A1, U57500430B2, DE102004007986A1, US2009085865A1, W02009046906A3, DE19T49418A1, DE102006028085Al, GB2455389A, US5S03145A, US5806514A, US2005205092A1, US20072839S3A1, US054117951 These patents do not address the use of a dive computer by means of a touch-sensitive display. 2
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    On the display of many dive computers nowadays also the pressure of the dive bottles is displayed. For this purpose, either a high-pressure sensor (usually around the 250-350 bar) is integrated in the dive computer and connected to the regulator by means of a high-pressure hose at the first stage or a cable-free pressure transmitter is mounted on the first stage. Uwatec (US5806514A) and Uemis, for example, use such pressure transmitters which are based on a wireless and digital protocol with an electromagnetic carrier frequency of approximately SkHz. The Swiss company Dynatron distributes a suitable electronic receiver module with the DMRQ1. Suunto also uses wireless transmission but with a carrier frequency of about SkHz and with a different transmission protocol. GH2465872A describes a transmission protocol based on 2 different frequencies for subsurface and above water,
    An alternative to the above wireless transmission methods is optical transmission. It is important that transmitter and receiver have visual contact. Alternatively, optical fibers can also be used for data transmission.
    In addition to inert gas absorption, the inert gas anesthetic must also be taken into account when diving. Air is about 78% nitrogen. Typically, scuba divers use compressed air or, more and more often, oxygen-depleted air as breathing gas which is carried in the scuba tanks. However, nitrogen acts narcotic from a certain depth and leads to the so-called deep intoxication. The depth, the softer the deep intoxication occurs, varies from individual to individual, and is also influenced by the state of the day, water temperature and mental factors.
    When deep and long dives are done, some or all of the nitrogen is replaced by a less narcotic gas such as helium. This is called mixed gas diving. Deep as well as long dives cause high nosy gas intakes in the body and the ascent to the surface involves numerous and sometimes long decompression stops.To accelerate decompression, additional respiratory gases carried in separate tanks are used.These so-called decompression gases typically contain less inert gases However, from 6m depth, accelerated decompression with pure oxygen is possible, and diving with multiple gas mixtures is known in the trade as "technical diving".
    Today, numerous dive computers are available on the market which can also calculate dives and decompression profiles with mixed gas or oxygen enriched air. If several gas mixtures are used for the decompression, the diver must make adjustments to the dive computer during the gas exchange in order to inform the dive computer which gas mixture is currently being used, so that the dive corpulator can carry out the calculation correctly. For adjustment, keys are usually used.
    Typical controls used on diving computers are: 13/09 2010 MO 11:02 [SE / EM NR 5138] lg] 007 13/00 2010 10:00 FAX 05776785702
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    Mechanical buttons: an external button presses an O-ring sealed mechanical feedthrough to operate a switch / button inside the pressure- and watertight case (many manufacturers, such as Suunto and Mares).
    Piezosch age: Under a thin membrane (usually made of aluminum) there is a Piezoelemerit- When temporally rapid pressure changes, the piezoelectric elements generate an electrical voltage which can be evaluated as a switching signal. The advantage of these switches is that no mechanical feedthroughs are necessary and thus a cost-effective and mechanically durable and reliable construction is possible (Shearwater, Ambient Pressure Diving, Divesystem).
    Magnetic switch: Another option that does not use O-ring seals are magnetic switches. A magnetic field-sensitive electrical element (magnetic sensor: reed contact or Hall sensor) is mounted inside the housing. During a switching process, a magnet is brought into the vicinity of the sensor, thus triggering a switching process. This solution is often used by manufacturers of underwater lamps, but also by dive computer manufacturers such as VR Technology. Disadvantage of this technology is that the magnets used for switching can disturb a compass, or makes it impossible to use an electronic compass integrated in the dive computer.
    Liq Division (GB2455389A) and Cochr.nn (U55899204A) use accelerometers instead of push buttons. Simple tapping on the dive computer is registered with the accelerometer at Cochran and used to toggle between different modes, Liquivision goes one step further and uses a three-dimensional sensor. Thus, a distinction can be made between knockers on different sides of the computer and a simple menu operation can be realized.
    However, since the number of input options is limited by the number of keys, setting changes are often only achievable with multiple key presses, which is time consuming and can be complicated. This is a problem especially in stressful situations. If, for example, during a technical dive a breathing gas fails unexpectedly, the diver changes to an alternative gas mixture. Such a situation requires focused and purposeful action. Fin Changing the breathing gas during technical dives also requires settings on the dive computer - a complicated operation of a dive computer is an additional stress factor. If several entries are necessary, these are often no longer free of errors in such a stressful situation. Incorrect settings on the dive computer lead to incorrect calculation of the inert gas saturations and can subsequently lead to decompression accidents. Most dive accidents are due to a chain of several causes - stress often plays a major role.
    Simple, fast and, above all, intuitive operation is not given, especially with extensive dive campers, which often have several menus: · and only a few - often only 1 - have control elements, Beisi jielweise you need with the Furyo dive computer for changing a gas mixture up to 7 test presses, and even more if a wrong key was pressed. 4
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    An alternative to conventional control elements are touch-sensitive displays - known in technical terms as touch screens or Toucl displays. Inputs can be made here directly by touching the display. Intuitive operation is easy to design as virtual controls - such as control buttons or a keyboard - are simply displayed on the screen (called virtual controls), and the user can input by touching the screen. Such displays are today used in large numbers in computers, pocket PCs (small computers with screen diag- ons of about 3-4 ") and cell phones.
    Touch-sensitive displays distinguish between the following technologies:
    Resistive touch-sensitive displays (4-wire or 5-wire) consist of two electrically conductive transparent foils, which are mounted at a certain distance from each other. Between the slides is a narrow cavity filled with air. Alternatively, there are also versions, we che consist of a conductive flexible film and a mechanically stable disc. The electrical conductivity is typically achieved by a transparent and electrically conductive coating e. A finger pressure brings now lower and upper foil together mechanically and in consequence electrically in contact. The films behave like a pair of voltage components. Based on the measured voltages in x and y direction, the position of the finger can be easily calculated. Unfortunately, a use of such a display underwater is not mc equal, since the increasing pressure of water, the air in the cavity is compressed and thus constantly an electrical connection between the upper and lower film is made. Thus, an operation under pressure is not possible. Capacitive touch-sensitive displays consist of an electrical insulating body - typically glass - which is equipped with optically transparent coatings (for example ITO). If you now touch the display, the charge changes at this point, which is detected and evaluated. Especially in salt water, which is electrically conductive, such a control element is not replaceable, since on the one hand the dielectric constant of salt water and the finger is in similar areas and is difficult to distinguish and on the other hand electrical charges are shorted by the good electrical conductivity of the water. When wearing gloves, the function of a capacitive touch-sensitive display is often compromised.
    Optical touch-sensitive displays are based on a series of infrared transmitting diodes and detectors which are aligned in x and y directionally on the edge of the display and which produce an x-y grid of small light barriers. An object / finger touching the display interrupts the infrared light rays at one point. With a corresponding electronics, the contact position is then calculated. A big advantage of these displays is that they can also be operated with gloves and can be made robust. They are often used in outdoor devices. In principle, such a control unit could also use underwater. A disadvantage of this type of displays However, the high power consumption, which is necessary for the operation of the IR transmitter diodes. It can also lead to erroneous inputs due to water turbidity and floating particles in the water.
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    In addition, the integration of the transmitting and receiving diodes impedes the constriction, resulting in a high production price. An optical touch-sensitive display is described in US2010201639A1.
    Practically all these displays can also be waterproofed. Operation underwater and under pressure is not possible. For example, CN2919719 describes a mobile phone equipped with a touch-sensitive display and waterproof (IPX55). The device also withstands repeated submersion in water. The patent does not describe the operation of the
    Device underwater.
    Touch-sensitive displays are already being used in watches and dive computers. US2009059730A1 describes a waterproof wristwatch with a touch-sensitive ring. The watch described therein is waterproof, but only the ring is touch-sensitive. There is no information as to whether the Tout h sensitivity is also underwater. However, since the patent is based on capacitive touch-sensitive sensors (claim 2), it can be assumed that the touch sensitivity underwater is not given.
    The watch manufacturer Tissot manufactures and distributes with the "5ea Touch". a dive computer with a touch-sensitive display, however, this display can only be used on the surface and deactivated underwater (Manual Sea Touch, Tissot, 145_EN, page 9, www.tissot.ch). DE102007047133A1 deals with the design of a housing for a dive computer. Under [0019] and claim no. 9, the integration of a touch screen is mentioned. Further, it is mentioned in [0018] that a scratch protection is preferably integrated from hardened glass (FIG. 2, 4a). Below this is the touch-sensitive sensor (Figure 2.4b). Also mentions that the touch screen underwater function is preferably disabled e. From this patent, it is not clear how a touch display must be designed to allow operation underwater.
    Problem: a) Representation of situational virtual control elements, which are displayed automatically in certain situations on the screen b) Simple operation c) Fast operation d) Intuitive operation e) Pressure and water-resistant touch-sensitive display which can be operated underwater
    The display of the controls can be generated with the appropriate software, which can automatically detect situations with the help of sensors (bottle pressure sensors, heart rate monitors, depth gauges). Thus, for example, with a Fluschendrucksensor the current air consumption can be determined. If this is too high, a warning is given (beeper or warning sign on 6
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    Display). Another example relates to technical dives in which gas changes are carried out. Here, the dive computer with the help of the ambient pressure sensor, the optimal depth for the Gaswechse! and then make suggestions on the display. At the same time, it is also conceivable that (in this case, the shape of the display is changed and, for example, virtual controls are faded in.) For better and clearer use of the display, all the virtual buttons can be hidden These functions are easily visualized by means of suitable software, but the key element is an underwater touch-sensitive display.
    The main problem division is therefore a touch-sensitive display in such a way that operation underwater and under increased pressure is perfectly possible.
    The invention solves the problem with a novel resistive touch-sensitive display in which the gap between the conductive layers is filled with an electrically insulating liquid or gel rather than air. Typically, either transparent and colorless silicone oil or silicone gel is used. As described above, gases are compressed under pressure. Unlike gases, however, fluids under pressure are largely incompressible. Even under high pressure, their volume does not change. Now, if the gap between the lower and upper film of the resistive display filled with oil, this Spait remains upright under elevated Außendrude and the lower and upper file electrically isolated from each other. A homogeneous over the surface of the display pressure (when diving) therefore does not lead to a deformation of the display foils. In the case of a touch with a finger - which corresponds to an inhomogeneous pressure effect - the foils are mechanically and electrically contacted at one location and the contact position can easily be determined with appropriate electronics. At this point, the oil is displaced, but since the foils are made flexible, this is not a problem, since the displaced oil leads only to a temporary slight outward curvature of the remaining touch-sensitive display surface. Temperature fluctuations lead to volume changes of the liquid. However, since the gap between the foils is very small, this leads only to a slight curvature of the surface of the touch-sensitive display which in no way affects the function of the display (an elevated temperature leads to a slight bulge, at a reduced temperature, the surface bulges slightly inside).
    Virtual controls: to increase the clarity of the display, all virtual controls are hidden. Only when the user touches the display, controls are displayed.
    Simple operation of the Dive Computer menu items can be selected by simply tapping - Situation Menus: The dive computer will suggest the depth of a gas change as a result of the throttle settings, and if this depth is reached, virtual keys will be automatically displayed to change the gases 7
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    Virtual Emergency Key: Pressing this virtual key will bring up function keys in which the dive computer's parameters will be modified to calculate an emergency climb.
    Notes and Messages: A virtual keyboard is displayed. In this way the diver can enter letters, words or whole sentences. These can be stored in the form of notes or sent as messages (SMS via mobile phone t eibt on the water surface and connected with a cable to the dive computer, or wireless solutions based on information transmission by radio or ultrasound).
    Photo album: just by tapping on the screen, saved photos can be retrieved. This is particularly useful for the determination of underwater fauna and flora.
    The mechanical assembly of a dive computer with a touch-sensitive display is done in several steps: 1) Production of the touch-sensitive display: The touch-sensitive display consists of 2 parts. The actual display (LCD or OLED technology) and the actual transparent and touch-sensitive unit which is mounted above the display. The components of the resistive contactor gssensitlven unit are manufactured in a conventional manner. The bottom and top of the touch-sensitive unit are welded or glued except for at least one opening. In a next step, the cavity between the film and the glass is filled with electrically insulating oil through the opening. To avoid air bubbles, this process is preferably done under vacuum or alternatively with degassed under vacuum oil. In the next step, the opening (s) are glued or welded (t) to permanently trap the oil and prevent the ingress of air. After thorough cleaning of the touch-sensitive unit, it is placed in the frame and glued on all sides with a suitable adhesive (for example epoxy-based adhesive). If it is a small series, it may be more cost effective to use commercially available touch sensitive units and fill them with the usual pressure relief port with oil. This requires a microinjection needle (diameter <200-300pm). However, this process is very time consuming and requires other work under a microscope or a powerful magnifying lens so as not to damage the touch-sensitive unit when the needle is inserted. 2) The electronics are then placed in the frame together with the actual display. 3} In the next step, the entire electronics, including the display, are encapsulated with silicone gel.
    Thus, the electronics are protected against water. At the same time, however, the ambient pressure is transmitted directly to the rear side of the touch unit by the gel, so that a homogeneous ambient pressure acts on the touch-sensitive unit from all sides.
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    Description of the figures:
    Figure l shows the structure of the dive computer. Above the LCD / OLED Disptay (5), the touch-sensitive unit {20) is attached. The touch-sensitive unit (20) is described in more detail in FIGS. 2 and 3 and consists of the four main components (1), (2), (3) and (4). The flexible side (1) of the touch-sensitive unit is on the outside * the rigid side (2), usually made of glass, is coated electrically conductive on the inside, the rigid side (2) on the outside. In order to avoid a direct short circuit of the two k itf ^ higen layers, the two layers by spacers (4) are separated from each other. The resulting cavity (3) between (1) and (2) is filled with silicone oil. Below d &gt; s displays (5) is an electronic board (6) attached. Ke terminals (13) of the touch-sensitive unit (20) are electrically connected to this board (either by means of a plug or airtight). The construction of the electronic board is described in more detail in FIG. The main components are a pressure sensor (10), a memory chip (11) and a microprocessor (9). Touch-sensitive unit (20) Firmly bonded to the housing (7) with epoxy resin. The housing (7) is equipped with three water contacts (15), and a battery compartment (8) equipped. These can be used to determine when the dive computer is submerged. This is done by means of impedance measurement between the contacts. Alternatively, these contacts can be used on land to connect to a personal computer (PC). By means of this connection, dive data can be read from the memory chip or the firmware of the dive computer can be reprogrammed. Longwave receiver and a memory chip available. The electronics are supplied with a 3V lithium battery (CR2), which is housed in a water and pressure-tight battery compartment (8) in the housing.
    Optionally, the dive computer is also equipped with a waterproof connector, which has 3 analog inputs, a digital output and a serial interface. The 3 analog inputs can be used, for example, to read the signals from oxygen sensors in a rebreather. The digital output can be used to drive the solenoid valve of a closed circuit device. Additional devices such as an oxygen saturation device (pulse oximeter) or a GP5 / GSM mobility unit, which is installed in a buoy, can be connected to the serial interface ,
    The interior of the dive computer is filled with silicone rubber (12) (seal from Wacker). This protects the electronics from water. At the same time, however, the gel transfers the water pressure to the pressure sensor (10) and thus enables a correct pressure measurement. Furthermore, the ambient pressure is transferred to the rear of the touch-sensitive unit. Thus, the pressure on the front and back of the display is always the same size and normally homogeneous. This has the advantage that the dive computer does not have to be equipped with a pressure-resistant windscreen.
    Figure 2 and Figure 3 show the detailed structure of the tube-sensitive unit (20). Figure 2 details the cross section and Figure 3 shows the top view. The flexible film (1) together with the (glass) disc (2) and the spacer i (4) forms a cavity (3) which is filled with silicone oil. (1) 9
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    POSTAMT SCHOTTDORF 1 ^ 1014 is equipped with a transparent electrically conductive layer on the underside and (2) on the top. The spacers (4) prevent the contacting from occurring. However, when the user touches the display, the top of the panel is made flexible, at the point of contact the two sheets are mechanically and electrically connected to each other. The electrical coatings of the upper side 11) of the touch-sensitive unit are contacted with 2 electrodes (18) and (19), the coatings of the disc (2) with the electrodes (16) and (17). The resistance of the electrical layers is usually between 100 and several 1000 ohms. The touch position detection happened: now as follows. In the first step, (18) is connected to the supply voltage and (19) to the electrical ground. If the electrical layers are brought into contact electrically by touching the film (1) at one point, then a voltage can be measured at the electrodes (16) and (17), which depends on the position of the contact point (the closer the contact point is) the electrode (18) is, the higher the voltage) Thus, the Y coordinate of the touch point can be determined. The X coordinate is determined by (16) grounded and (17) with the supply voltage and the voltage across the electrodes (18) and (19) measured. The electrodes are connected by means of a ribbon cable (13) to the electronic board (6) and then further to the microprocessor (9).
    FIG. 4 schematically describes the structure of the electrore: the heart of the electronic circuit board is an 8-bit microprocessor (9) (Atmegal284P, Atmel). For pressure / depth measurement, a digital pressure sensor (10) from the Swiss company Intersema (M55541) is used. A graphic LC display (5) (Elecronic Assembly, EA DOGM 128-6) is connected to the serial peripheral interface (SPI) of the microprocessor. The starting basis for the touch-sensitive unit (20) is a touch-sensitive input unit from Electronic Assembly (EA TOUCH118 * 1). The unit is opened before installation, infested with silicone oil and then pre-glued. The 4 electrodes (16), (17), (18) and (19) are connected to ports PortA 0,1, 2 and 3 of the microprocessor. The ports of PortA can be software configured as either inputs or outputs or as analog inputs, allowing for easy readout of the touch-sensitive unit. When the dive computer is not in use, a sleep mode is activated. In this mode, many electronic components are switched off and thus the total power consumption is reduced to a few μΑ. In this mode, the electrodes (18) and (19) are electronically connected to ground and the voltage is input to (16) and (17). (16) and (17) are connected to the supply voltage via a so-called pull-up resistor. If someone touches the touch-sensitive unit, the voltage drops (16) and (17) and a hardware interruption is triggered. This is used to "wake up" the dive computer from power saving mode (or sleep mode). For storing dive data, Flash Memory is integrated (11) (Atmel, Dataflash). An infrared receiver (22) allows receipt of false print data from a bottle optical pressure transmitter. For this purpose, a Fiaschendrucksender is connected to the scuba tank, which measures the bottle pressure and sends in the form of a coded infrared signal to the dive computer. The infrared light can be transmitted either through the water or by means of a glass fiber. 10
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    Alternatively, transmission with light at a different wavelength may be used. A 5 kHz long-wave receiver (23) allows the reception of signals from bottle pressure transmitters from Suunto. In addition, signals from a heart rate chest belt can also be evaluated with this receiver. Optionally, the rope computer can be equipped with a tilt compensated compass. The required electronic components are then a 3-axis magnetometer (24) (HMC5843, Honeywell) for measuring the magnetic field and an analog 3-axis acceleration sensor (25) (MMA7341, Freescale) for position detection and inclination compensation of the magnetometer. For power supply a 3V lithium battery is used (21) (CR2) 11 13/09 2010 MO 11:02 [SE / EM NR 5136] @ 015
    权利要求:
    Claims (1)
    [1]
    13/09 2010 10:02 FAX 05776785702 POST OFFICE SCHÜTTDORF @ 016

    Claims; 1) touch-sensitive display with mi idstens a display and a transparent touch-sensitive Eingabeeinhei t which is mounted before the Angeige, characterized in that the touch: ssensitivity is also underwater and under increased pressure. 2) Touch-sensitive display according to claim 1, characterized in that the touch-sensitive input unit is insensitive to homogeneous pressure loads, which are caused by the underwater increased ambient pressure. 3) Touch-sensitive display! one of the preceding claims, characterized in that the touch-sensitive unit is designed as a resistive touch-sensitive unit. 4) touch-sensitive display according to claim 1, characterized in that at least one cavity in the touch-sensitive unit is filled with an electrically insulating liquid, 5) touch-sensitive display according to claim 1, characterized in that at least one cavity is filled with an electrically insulating gel , 6) Touch-sensitive display according to claim 1, characterized in that both sides of the touch-sensitive unit are exposed to the ambient pressure. 7) Method for operating a dive computer, characterized in that user inputs are made via a touch-sensitive display. 8) Method according to claim 7, characterized in that controls are displayed on the display. 9) Method according to claim 8, dadurc n characterized in that Bedieneiemente are displayed automatically and situation-based 10) Method according to claim 7, characterized in that the Stormsparmsdus of a dive computer is terminated by touching the display device. 12 13/03 2010 MO 11:02 [SE / EM HR 5138] @ 016
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    同族专利:
    公开号 | 公开日
    AT510385A3|2017-04-15|
    AT510385B1|2017-04-15|
    EP2616911A1|2013-07-24|
    WO2012035021A1|2012-03-22|
    EP2616911B1|2016-05-25|
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    法律状态:
    2017-08-15| PC| Change of the owner|Owner name: JOHNSON OUTDOORS INC., US Effective date: 20170619 |
    2021-05-15| MM01| Lapse because of not paying annual fees|Effective date: 20200913 |
    优先权:
    申请号 | 申请日 | 专利标题
    ATA1512/2010A|AT510385B1|2010-09-13|2010-09-13|TOUCH-SENSITIVE DISPLAY AND METHOD FOR OPERATING A DIVE COMPUTER|ATA1512/2010A| AT510385B1|2010-09-13|2010-09-13|TOUCH-SENSITIVE DISPLAY AND METHOD FOR OPERATING A DIVE COMPUTER|
    PCT/EP2011/065866| WO2012035021A1|2010-09-13|2011-09-13|Touch-sensitive display, and method for the operator control of a diving computer|
    EP11757845.0A| EP2616911B1|2010-09-13|2011-09-13|Diving computer with touch-sensitive display and method of operation of the diving computer|
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