Communication interface for a path measuring device
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01S-003/80
G01S-003/00
H04B-003/46
출원번호
US-0099127
(2002-03-15)
등록번호
US-7430236
(2008-09-30)
우선권정보
DE-101 13 716(2001-03-19)
발명자
/ 주소
Eberle,Hans Juergen
Burkhardt,Thomas
Buehlmeyer,Bernd
출원인 / 주소
Balluff GmbH
대리인 / 주소
Lipsitz & McAllister, LLC
인용정보
피인용 횟수 :
2인용 특허 :
7
초록▼
A communication interface for a path measuring device is provided. The interface can be coupled between the path measuring device and a control device. A path determination can be carried out by the path measuring device by way of a measurement of the propagation time of measurement signals. A meas
A communication interface for a path measuring device is provided. The interface can be coupled between the path measuring device and a control device. A path determination can be carried out by the path measuring device by way of a measurement of the propagation time of measurement signals. A measurement of the propagation time can be triggered by way of control signals on a control signal communication channel. A propagation-time signal communication channel is provided for propagation-time signals. The present invention enables a path measuring device to be used universally and in a simple manner, as the communication interface may be coupled to the control signal communication channel and/or to the propagation-time signal communication channel and digital data may be transmittable between the control device and the path measuring device in addition to control signals for the measurement of the propagation time and propagation-time signals.
대표청구항▼
The invention claimed is: 1. Communication interface for a path measuring device, a distance measurement being carried out by means of the path measuring device by way of a measurement of the propagation time of measurement signals, the measurement of the propagation time being triggered by way of
The invention claimed is: 1. Communication interface for a path measuring device, a distance measurement being carried out by means of the path measuring device by way of a measurement of the propagation time of measurement signals, the measurement of the propagation time being triggered by way of control signals from a control device to the path measuring device on a control signal communication channel, a propagation-time signal communication channel being provided for propagation-time signals from the path measuring device to the control device, said interface comprising: a microcontroller controlling data exchange between the control device and the path measuring device, means for coupling the communication interface to the control signal communication channel and the propagation-time signal communication channel, means responsive to the microcontroller for receiving signals from at least one of the control signal communication channel and the propagation-time signal communication channel, means responsive to the microcontroller for transmitting digital data between the control device and the path measuring device via the interface, said digital data transmitted via the communication interface being one of: (a) combined with one of the control signal or the propagation time signal for transmission; and (b) transmitted separately from the control signals for the measurement of the propagation time and the propagation-time signals, wherein: the path measuring device comprises a path transducer; the measurement signal comprises a mechanical wave propagated in or on said transducer; the communication interface is coupled between the path measuring device and the control device; a starting flank of a control pulse of the control signal triggers a measurement signal for measuring of the propagation time through said path measuring device for use in making said distance measurement; and a pulse duration of the control pulse triggering the measurement of the propagation time has an instruction effect for the path measuring device. 2. Communication interface as defined in claim 1, wherein the transmission of data is shifted in time in relation to at least one of the control signals and the propagation-time signals. 3. Communication interface as defined in claim 1, wherein the propagation-time signals comprise starting signals for triggering a measurement of the propagation time and stop signals, wherein the propagation time results from a time interval between starting signals and associated stop signals. 4. Communication interface as defined in claim 3, wherein a control signal triggers the starting signal for triggering the measurement of the propagation time. 5. Communication interface as defined in claim 3, wherein the transmission of the stop signals is blocked during the transmission of data. 6. Communication interface as defined in claim 1, wherein the digital data are transmittable serially between the control device and the path measuring device. 7. Communication interface as defined in claim 1, wherein the digital data are transmittable bit-serially between the control device and the path measuring device. 8. Communication interface as defined in claim 1, wherein an information unit for the transmission of the data between control device and path measuring device comprises N bits. 9. Communication interface as defined in claim 8, wherein the information unit begins with a starting bit. 10. Communication interface as defined in claim 1, wherein at least one of instructions and parameters are transmittable to the path measuring device. 11. Communication interface as defined in claim 10, wherein the transmission of the at least one of the instructions and parameters to the path measuring device takes place on the control signal communication channel. 12. Communication interface as defined in claim 10, wherein response data of the path measuring device to the at least one of the instructions and parameters received are transmittable to the control device. 13. Communication interface as defined in claim 12, wherein the transmission of the response data takes place on the propagation-time signal communication channel. 14. Communication interface as defined in claim 1, wherein at least one of event data and parameter data of the path measuring device are transmittable to the control device. 15. Communication interface as defined in claim 14, wherein the transmission of the at least one of the event data and parameter data takes place on the propagation-time signal communication channel. 16. Communication interface as defined in claim 14, wherein the path measuring device sends the at least one of the event data and parameters cyclically to the control device. 17. Communication interface as defined in claim 1, wherein the pulse duration of the control pulse triggering the measurement of the propagation time is adjustable. 18. Communication interface as defined in claim 1, wherein at least one of an instruction and parameter is transmitted to the path measuring device when a certain pulse duration threshold is exceeded. 19. Communication interface as defined in claim 18, wherein the transmission of the at least one of the instructions and parameters take place at a certain time interval in relation to the control pulse. 20. Communication interface as defined in claim 1, wherein the communication interface is coupled to the respective communication channels via multiplexers. 21. Communication interface as defined in claim 1, wherein the path transducer acts magnetostrictively. 22. Communication interface as defined in claim 1, wherein at least one of the communication channels is unidirectional. 23. Communication interface as defined in claim 1, wherein at least one of the communication channels is bidirectional. 24. Communication interface as defined in claim 1, wherein: the control signal communication channel and the propagation time signal communication channel are separate unidirectional communication channels; said control signal communication channel communicates in a first direction between said control device and said path measuring device; and said propagation time signal communication channel communicates in a second direction between said path measuring device and said control device. 25. Path measuring system, comprising: a control device; one or more path measuring devices couplable to the control device, a distance measurement being carried out via a measurement of the propagation time of measurement signals within said path measuring device or devices, a control signal communication channel for triggering a measurement of the propagation time, a propagation-time signal communication channel for propagation-time signals, and a communication interface coupled between the control device and the one or more path measuring devices to at least one of the control signal communication channel and the propagation-time signal communication channel, wherein: at least one of said one or more path measuring devices comprises a path transducer having a waveguide in which mechanical waves propagate; the measurement signals comprise mechanical waves propagated in or on said transducer; the distance measurement is carried out via a measurement of the propagation time of the measurement signals within the waveguide; digital data are transmittable between the control device and the path measuring device via the communication interface, said digital data transmittable via the communication interface being one of: (a) combined with one of the control signal or the propagation time signal for transmission; and (b) transmitted separately from the control signals for the measurement of the propagation time and the propagation-time signals; a starting flank of a control pulse of the control signal triggers a measurement signal for measuring of the propagation time through said path measuring device for use in making said distance measurement; and a pulse duration of the control pulse triggering the measurement of the propagation time has an instruction effect for the path measuring device. 26. Path measuring system as defined in claim 25, comprising a plurality of path measuring devices. 27. Path measuring system as defined in claim 25, wherein the control device is connected to the path measuring devices via a data bus. 28. Path measuring system as defined in claim 27, wherein a specific path measuring device is adapted to be addressed by the control device via an address identification. 29. Method for the control of a path measuring device comprising: measuring the propagation time of measurement signals via a path measuring device to provide a distance measurement, transmitting control signals from a control device for triggering a measurement of the propagation time via a control signal communication channel, and transmitting propagation-time signals on a propagation-time signal communication channel, wherein: at least one of said one or more path measuring devices comprises a path transducer having a waveguide in which mechanical waves propagate; the measurement signals comprise mechanical waves propagated in or on said transducer; the distance measurement is carried out via a measurement of the propagation time of the measurement signals within the waveguide; digital data are transmitted between the control device and the path measuring device via a communication interface, said digital data transmittable via the communication interface being one of: (a) combined with one of the control signal or the propagation time signal for transmission; and (b) transmitted separately from the control signals and the propagation-time signals, the communication interface coupled between the control device and the path measuring device to at least one of the control signal communication channel and the propagation-time signal communication channel; a starting flank of a control pulse of the control signal triggers a measurement signal for measuring of the propagation time through said path measuring device for use in making said distance measurement; and a pulse duration of the control pulse triggering the measurement of the propagation time has an instruction effect for the path measuring device. 30. Method as defined in claim 29, wherein the transmission of data is shifted in time in relation to at least one of the control signals and the propagation-time signals. 31. Method as defined in claim 29, wherein the propagation-time signals comprise starting signals for triggering a measurement of the propagation time and stop signals, wherein the propagation time results from a time interval between starting signals and associated stop signals. 32. Method as defined in claim 31, wherein a control signal triggers the starting signal for triggering the measurement of the propagation time. 33. Method as defined in claim 31, wherein the transmission of the stop signals is blocked during the transmission of data. 34. Method as defined in claim 29, wherein the digital data are transmittable serially between the control device and the path measuring device. 35. Method as defined in claim 29, wherein the digital data are transmittable bit-serially between the control device and the path measuring device. 36. Method as defined in claim 29, wherein an information unit for the transmission of the data between control device and path measuring device comprises N bits. 37. Method as defined in claim 36, wherein the information unit begins with a starting bit. 38. Method as defined in claim 29, wherein at least one of instructions and parameters are transmittable to the path measuring device. 39. Method as defined in claim 38, wherein the transmission of the at least one of the instructions and parameters to the path measuring device takes place on the control signal communication channel. 40. Method as defined in claim 38, wherein response data of the path measuring device to the at least one of the instructions and parameters received are transmittable to the control device. 41. Method as defined in claim 40, wherein the transmission of the response data takes place on the propagation-time signal communication channel. 42. Method as defined in claim 29, wherein at least one of event data and parameter data of the path measuring device are transmittable to the control device. 43. Method as defined in claim 42, wherein the transmission of the at least one of the event data and parameter data takes place on the propagation-time signal communication channel. 44. Method as defined in claim 42, wherein the path measuring device sends the at least one of the event data and parameters cyclically to the control device. 45. Method as defined in claim 29, wherein the pulse duration of the control pulse triggering the measurement of the propagation time is adjustable. 46. Method as defined in claim 29, wherein at least one of an instruction and parameter is transmitted to the path measuring device when a certain pulse duration threshold is exceeded. 47. Method as defined in claim 46, wherein the transmission of the at least one of the instructions and parameters take place at a certain time interval in relation to the control pulse. 48. Method as defined in claim 29, wherein the communication interface is coupled to the respective communication channels via multiplexers. 49. Method as defined in claim 29, wherein the path transducer acts magnetostrictively. 50. Method as defined in claim 29, wherein at least one of the communication channels is unidirectional. 51. Method as defined in claim 29, wherein at least one of the communication channels is bidirectional.
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이 특허에 인용된 특허 (7)
Laird Douglas (Los Gatos CA) D\Souza Godfrey P. (Santa Clara CA), Delay compensator and monitor circuit having timing generator and sequencer.
Abramovich Igor A. (Simsbury CT) McKenna Neil (Simsbury CT), Detection of damped sine waves in a magnestostrictive displacement transducer using pretrigger and detection thresholds.
Blaes Brent R. (Temple City CA) Buehler Martin G. (La Canada CA), Method and apparatus for characterizing propagation delays of integrated circuit devices.
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