Generic interface adapter builder software generates an interface adapter to tie tools into a centralized manufacturing execution system. As contemplated by embodiments of the present invention, the interface adapter allows a tool in a semiconductor manufacturing assembly to communicate with other h
Generic interface adapter builder software generates an interface adapter to tie tools into a centralized manufacturing execution system. As contemplated by embodiments of the present invention, the interface adapter allows a tool in a semiconductor manufacturing assembly to communicate with other hardware and software in the centralized manufacturing execution system in accordance with a standard protocol and be operable from a common view graphical user interface. The generic interface builder software uses a classification of the type library and desired parameters for a particular tool to generate the interface adapter that maps the interface methods of the tool to the interface of the manufacturing execution system and handles long running service request support. In one aspect of the invention, the tool to be integrated into the manufacturing assembly may be a material control system. As contemplated by embodiments of the present invention, the material control system uses COM-based interface methods, and may optionally include a COM-based protocol converter, and may expose its interface methods via a type library.
대표청구항▼
Generic interface adapter builder software generates an interface adapter to tie tools into a centralized manufacturing execution system. As contemplated by embodiments of the present invention, the interface adapter allows a tool in a semiconductor manufacturing assembly to communicate with other h
Generic interface adapter builder software generates an interface adapter to tie tools into a centralized manufacturing execution system. As contemplated by embodiments of the present invention, the interface adapter allows a tool in a semiconductor manufacturing assembly to communicate with other hardware and software in the centralized manufacturing execution system in accordance with a standard protocol and be operable from a common view graphical user interface. The generic interface builder software uses a classification of the type library and desired parameters for a particular tool to generate the interface adapter that maps the interface methods of the tool to the interface of the manufacturing execution system and handles long running service request support. In one aspect of the invention, the tool to be integrated into the manufacturing assembly may be a material control system. As contemplated by embodiments of the present invention, the material control system uses COM-based interface methods, and may optionally include a COM-based protocol converter, and may expose its interface methods via a type library. e decrement amount is the same value from one cardiac cycle to the next cardiac cycle. 6. A method for operating a dual-chamber pacemaker, wherein the dual chamber pacemaker is electrically coupled to a heart, the pacemaker receives Vsense events from the heart indicated possible premature ventricular contraction, the pacemaker has a trigger zone interval after the Apace for detecting Vsense events to administer a ventricular safety pace (VSP), and wherein the pacemaker has an overall ventricular to ventricular (V2V) pacing interval for pacing the cardiac cycle, the method comprising the steps of: increasing the overall pacing interval responsive to detecting Vsense events; and decreasing the overall pacing interval responsive to all recent overall pacing intervals having a minimum DV2V interval, where DV2V represents the minimum V2V interval ending in a ventricular pace that is long enough so as to not interfere with arrhythmia detection. 7. A method as in claim 6, wherein the decreasing step is responsive to the recent overall pacing intervals, wherein the recent overall pacing intervals include the previous N cardiac cycles, wherein N represents an integer. 8. A method as in claim 7, wherein the decreasing step utilizes N being less than 10 cardiac cycles. 9. A method as in claim 6, wherein the decreasing step decreases the overall pacing interval not less than the upper activity interval, wherein the upper activity interval represents the minimum V2V escape interval for brady pacing. 10. A method as in claim 6, wherein the increasing step increases the overall pacing interval not greater than the VSP V2V upper limit, wherein the VSP V2V upper limit represents the minimum V2V escape interval following a ventricular safety pace that will insure that the safety pace does not interfere with arrhythmia detection. 11. A method for operating a dual-chamber pacemaker, wherein the dual chamber pacemaker is electrically coupled to a heart, the pacemaker is adapted to administer paces to the atrium (Apaces), the pacemaker detects Vsense events from the heart indicating possible premature ventricular contraction, and the pacemaker detects Vpace events indicating a ventricle has been paced but not with a safety pace, wherein the pacemaker has a blanking interval following the Apace, and the pacemaker has a trigger zone interval after the blanking interval for detecting Vsense events to generate a ventricular safety pace (VSP) to the ventricle at the end of an A2V VSP interval, and wherein the pacemaker has an overall ventricular to ventricular (V2V) pacing interval for pacing the cardiac cycle, the method comprising the steps of: increasing the trigger zone interval responsive to not detecting VSP events,; and decreasing the trigger zone interval responsive to detecting VSP events. 12. A method as in claim 11, wherein the decreasing and increasing step detecting elements are responsive to detecting N VSP events in the previous M time slots, wherein N is an integer, and M has units of time. 13. A method as in claim 11, wherein the decreasing and increasing step detecting elements are responsive to detecting N VSP events in the previous M time slots, wherein N is an integer, and M has units of cardiac cycles. 14. A method as in claim 12, wherein M is less than 10 seconds. 15. A method as in claim 11, wherein the increasing step does not increase the trigger zone interval past the end of the combined blanking interval and the A2V VSP interval. 16. A method as in claim 11, wherein the decreasing step decreases the trigger zone interval independently of the A2V VSP interval. 17. A method as in claim 11, wherein the decreasing step decreases the trigger zone while the A2V VSP interval remains substantially unchanged. 18. A method for operating a dual-chamber pacemaker, wherein the dual chamber pacemaker is electrically coupled to a heart, the pacemaker is adapted to administer paces to the atrium (Apaces), the pacemaker detects V sense events from the heart indicating possible premature ventricular contraction, and the pacemaker detects Vpace events indicating that a ventricle has been paced but not with a safety pace, wherein the pacemaker has a trigger zone interval after the Apace for detecting Vsense events in time to administer a ventricular safety pace at the end of A2V VSP interval, and wherein the pacemaker has an overall pacing interval for pacing the cardiac cycle, and further wherein the pacemaker has a PAV interval, with the PAV interval representing the interval between the Apace and the next scheduled Vpace, and the pacemaker calculates a V2V interval, wherein the V2V interval represents the time from the previous ventricular interval to the current ventricular event, wherein the pacemaker calculates a DV2V interval, where the DV2V interval represents the minimum V2V interval ending in a ventricular pace that is long enough so as to not interfere with arrhythmia detection, the method comprising the steps of: (a) waiting for detection of a ventricular event selected from the group consisting of Vsense and Vpace, then executing steps (b) and (c); (b) upon detection of the ventricular event, if the most recent V2V interval is not less than the DV2V interval, and all of the most recent N V2V intervals were greater than or equal to DV2V, where N is an integer, then increasing the PAV value, but not increasing the PAV above an upper limit, where the PAV value is used to schedule the next Vpace; and (c) upon detection of the ventricular event, if the most recent V2V interval is less than the DV2V interval, then decreasing the PAV value, but not below a lower limit, where the PAV value is used to schedule the next Vpace. 19. A method as in claim 18, wherein the increasing PAV interval step (b) increases the PAV interval by an increment amount, wherein the increment amount is the same value from one cardiac cycle to the next cardiac cycle. 20. A method as in claim 18, wherein the decreasing PAV interval step (c) decreases the PAV interval by a decrement amount, wherein the decrement amount is the same value from one cardiac cycle to the next cardiac cycle. 21. A method as in claim 18, wherein the increasing and decreasing PAV interval steps increase and decrease the PAV interval while leaving the overall cardiac V2V interval substantially unchanged. 22. A method for operating a dual-chamber pacemaker, wherein the dual chamber pacemaker is electrically coupled to a heart, the pacemaker is adapted to administer paces to the atrium (Apaces), the pacemaker detects Vsense events from the heart indicating possible premature ventricular contractions, and the pacemaker detects Vpace events indicating a ventricle has been paced but not with a safety pace, wherein the pacemaker has a trigger zone interval after the Apace for detecting Vsense events to administer a ventricular safety pace at the end of a A2V VSP interval, and wherein the pacemaker has an overall ventricular to ventricular (V2V) pacing interval for pacing the cardiac cycle, and the pacemaker has a PAV interval, wherein the PAV interval represents the interval between the Apace and the next scheduled Vpace, the method comprising the steps of: increasing the PAV interval responsive to not detecting VSP events; and decreasing the PAV interval responsive to detecting VSP events. 23. A method as in claim 22, wherein the increasing PAV interval step is responsive to all of the most recent N V2V intervals being at least the length of a DV2V interval, where N is an integer, wherein the DV2V interval represents the minimum V2V interval ending in a ventricular pace that is long enough so as to not interfere with arrhythmia detection. 24. A method as in claim 22, wherein the decreasing PAV interval step is responsive to at least some the most recent V2V interval being less than the length of a DV2V interval, wherein the DV2V interval represents the minimum V2V interval ending in a ventricul
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