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A system and method for efficiently and relatively inexpensively providing a capability of translating "Patient Session Information" comprising IMD data and patient data stored in IMD memory in one human language and optionally other patient data from other sources into another human language. The l

A system and method for efficiently and relatively inexpensively providing a capability of translating "Patient Session Information" comprising IMD data and patient data stored in IMD memory in one human language and optionally other patient data from other sources into another human language. The local language translation is effected by first employing an Extensible Mark-up Language (XML) converter for converting Patient Session Information from an initial format, such as a memory dump format, ASCII format, a waveform format, a numeric format, or a binary format, to an XML format, thereby providing XML formatted Patient Session Information. Then, the XML formatted Patient Session Information is subjected to transformation by a human language specific Extensible Stylesheet Language (XSL) stylesheet into XSL transformed Patient Session Information. The XSL stylesheet effects translation of the XML formatted Patient Session Information into a language understandable to the user in an HTML format or another XML format or another suitable format, e.g., PDF or SVG graphic image formats. The XSL transformed Patient Session Information is thereby rendered understandable to the user that selects the human language when the translated Patient Session Information is delivered as by visual display or print-out or audible presentation or storage depending upon a selection of the user. The translated Patient Session Information can be stored in the programmer memory or in the IMD memory or transferred or exported to another device or system interconnected with the programmer including a remote server accessed through the Internet.

대표청구항 ▼

A system and method for efficiently and relatively inexpensively providing a capability of translating "Patient Session Information" comprising IMD data and patient data stored in IMD memory in one human language and optionally other patient data from other sources into another human language. The l

A system and method for efficiently and relatively inexpensively providing a capability of translating "Patient Session Information" comprising IMD data and patient data stored in IMD memory in one human language and optionally other patient data from other sources into another human language. The local language translation is effected by first employing an Extensible Mark-up Language (XML) converter for converting Patient Session Information from an initial format, such as a memory dump format, ASCII format, a waveform format, a numeric format, or a binary format, to an XML format, thereby providing XML formatted Patient Session Information. Then, the XML formatted Patient Session Information is subjected to transformation by a human language specific Extensible Stylesheet Language (XSL) stylesheet into XSL transformed Patient Session Information. The XSL stylesheet effects translation of the XML formatted Patient Session Information into a language understandable to the user in an HTML format or another XML format or another suitable format, e.g., PDF or SVG graphic image formats. The XSL transformed Patient Session Information is thereby rendered understandable to the user that selects the human language when the translated Patient Session Information is delivered as by visual display or print-out or audible presentation or storage depending upon a selection of the user. The translated Patient Session Information can be stored in the programmer memory or in the IMD memory or transferred or exported to another device or system interconnected with the programmer including a remote server accessed through the Internet. said breech block and launching said projectile from said barrel, said breech block moving in said main chamber away from said one end of said barrel, said launch sequence opening said low pressure valve and moving said pin out of contact with said projectile in said feed chamber, said projectile in said feed chamber moving into said main chamber between said breech block and said one end of said barrel, said low pressure on said low pressure side of said breech block moving said breech block toward said one end of said barrel to provide repeated launchings of projectiles from said ship. 2. The combination of claim 1 further comprising said controller including an electrical circuit of a plurality of solenoids activated by microswitches connected with said trigger and said valves. 3. The combination of claim 2 further comprising said controller including a timed sequence of activation. 4. The combination of claim 2 further comprising an automatic continuous timed sequence during activation of said trigger. 5. The combination of claim 2 further comprising a sensor in said main chamber connected to said controller to indicate the presence of said projectile and launching condition. 6. The combination of claim 1 further comprising an aiming device on said air cannon for determining azimuth and elevation of the barrel. 7. The combination of claim 6 further comprising a laser aiming device. 8. The combination of claim 6 further comprising a strobe aiming device. 9. The combination of claim 3 further comprising said projectiles being biodegradable whereby said projectiles do not pollute the water about said ship. 10. The combination of claim 9 further comprising said projectiles being approximately the size and shape of a golf ball. 11. The combination of claim 1, wherein said base is rotatably and pivotably connected to said main chamber, said controller opening said at least one high pressure valve for approximately 0.50 seconds upon actuation of said trigger to launch said projectile, said controller opening said at least one low pressure valve approximately 1.12 seconds later to move said breech block toward said one end of said barrel, said at least one high pressure valve and said at least one low pressure valve adapted to be connected to a source of pressurized gas. 12. The combination of claim 11 further comprising said controller including a motor and a shaft, said shaft having a plurality of discs, each disc having at least one indentation, a series of microswitches in contact with said discs whereby as said motor rotates said shaft said indentations cause said microswitches to move, said movement of said microswitches resulting in a launch sequence. ompare the measured velocity with a desired velocity range. 8. A paintball gun according to claim 7, wherein the electronic circuit board is further configured to cause the measured velocity to fall within the desired velocity range. 9. A paintball gun according to claim 8, wherein the electronic circuit board is configured to adjust a dwell setting of the solenoid to increase the measured velocity. 10. A dynamic control circuit for a paintball gun, said circuit comprising: means for determining a velocity of a paintball exiting a paintball gun; means for comparing the determined velocity to a desired velocity; and means for adjusting a delay between shots of the paintball gun to cause the velocity to substantially conform to the desired velocity. 11. A dynamic control circuit according to claim 10, wherein the means for determining comprises a sensor. 12. A dynamic control circuit according to claim 10, wherein the means for comparing comprises an electronic circuit board. 13. A dynamic control circuit according to claim 10, wherein the means for adjusting comprises an electronic circuit board. 14. A dynamic control circuit according to claim 11, wherein the sensor is configured to measure a pressure. 15. A dynamic control circuit according to claim 14, wherein the means for adjusting is configured to control a dwell setting of a solenoid of the paintball gun to cause the measured pressure value to conform to a desired pressure value. 3532, 19760800, Litz, 123/075.CC; US-4248185, 19810200, Jaulmes, 123/073.R; US-4250844, 19810200, Tews, 123/073.AV; US-4280455, 19810700, Yamaguchi et al., 123/196.M; US-4290511, 19810900, de Baan et al.; US-4294202, 19811000, Boyesen, 123/073.PP; US-4321893, 19820300, Yamamoto, 123/065.PE; US-4364307, 19821200, Paro, 092/157; US-4388895, 19830600, Boyesen, 123/073.PP; US-4395978, 19830800, Boyesen, 123/073.R; US-4432925, 19840200, Holtzberg et al., 264/235; US-4481910, 19841100, Sheaffer, 123/073.R; US-4481917, 19841100, Rus et al., 123/190.C; US-4598673, 19860700, Poehlman, 123/073.PP; US-4630591, 19861200, Hooper, 123/073.PP; US-4829946, 19890500, Boyesen, 123/065.PE; US-4909193, 19900300, Boyesen, 123/065.PE; US-4911115, 19900300, Boyesen, 123/065.PE; US-4924819, 19900500, Boyesen, 123/065.PE; US-5002025, 19910300, Crouse, 123/196.M; US-5396867, 19950300, Ito et al., 123/041.39; US-5513608, 19960500, Takashima et al., 123/196.W; US-5572967, 19961100, Donaldson, Jr., 123/190.12; US-5638780, 19970600, Duvinage et al., 123/065.VA; US-5755194, 19980500, Moorman et al., 123/196.W; US-5983851, 19991100, Kimijima et al., 123/196.W; US-6085703, 20000700, Noguchi, 123/073.R; US-6112708, 20000900, Sawada et al., 123/073.R; US-6152093, 20001100, Sawada et al., 123/073.PP; US-6216650, 20010400, Noguchi, 123/073.A; US-6240886, 20010600, Noguchi, 123/732; US-6289856, 20010900, Noguchi, 123/073.PP 607/060; US-6169925, 20010100, Villaseca et al., 607/060; US-6263246, 20010700, Goedeke et al., 607/060