Gas monitor

US 20060044562A1
Filed: 08/25/2004
Published: 03/02/2006
Est. Priority Date: 08/25/2004
Status: Abandoned Application

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1. Gas detection apparatus comprising, an optical source unit including a tunable diode laser, an optical detection unit including a light sensitive detector, the source and the detector being arranged so that light from the source propagates through a gas measurement volume prior to being received by the detector, and the source being adapted to scan the light wavelength across one or more expected absorption lines of gases in the measurement volume, a control and processing unit for control and modulation of the source and processing of the detected signal and for calculating at least one digital value representing (a) gas concentrations in the gas measurement volume, wherein said control and processing unit is coupled to the source via a digital-to-analogue (d/a) converter, and the detector output signal is coupled to the input of an analogue-to-digital (a/d) converter, and the output of the a/d converter is coupled to the processing unit, and the control and processing unit is adapted to perform essentially digital signal processing, and to calculate said at least one digital value taking into account the amplitude and the width of each gas absorption line detected:

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Abstract

Gas detection or monitoring apparatus mainly comprising, an optical source unit including a tunable diode laser, an optical detection unit including a light sensitive detector, the source and the detector being arranged so that light from the source propagates through a gas measurement volume prior to being received by the detector, and the source being adapted to scan the light wavelength across one or more expected absorption lines of gases in the measurement volume, a control and processing unit for control and modulation of the source and processing of the detected signal and for calculating at least one digital value representing (a) gas concentrations in the gas measurement volume, wherein said control and processing unit is coupled to the source via a digital-to-analogue (D/A) converter, and the detector output signal is coupled to the input of an analogue-to-digital (A/D) converter, and the output of the A/D converter is coupled to the processing unit.

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35 Claims

1. Gas detection apparatus comprising, an optical source unit including a tunable diode laser, an optical detection unit including a light sensitive detector, the source and the detector being arranged so that light from the source propagates through a gas measurement volume prior to being received by the detector, and the source being adapted to scan the light wavelength across one or more expected absorption lines of gases in the measurement volume, a control and processing unit for control and modulation of the source and processing of the detected signal and for calculating at least one digital value representing (a) gas concentrations in the gas measurement volume, wherein said control and processing unit is coupled to the source via a digital-to-analogue (d/a) converter, and the detector output signal is coupled to the input of an analogue-to-digital (a/d) converter, and the output of the a/d converter is coupled to the processing unit, and the control and processing unit is adapted to perform essentially digital signal processing, and to calculate said at least one digital value taking into account the amplitude and the width of each gas absorption line detected:
- View Dependent Claims (2, 3, 4, 5, 6, 7, 24, 25, 26)
- - 2. Apparatus according to claim 1, where the detector output is coupled directly to the analogue-to-digital converter.
  - 3. Apparatus according to claim 1, where the detector output is coupled to the analogue-to-digital converter via an amplifier.
  - 4. Apparatus according to claim 1, wherein the detector output signal is directly converted in the A/D converter into a digital signal representation, and all signal processing functions in said control and processing unit are performed in the digital domain.
  - 5. Apparatus according to claim 1, wherein said A/D-converter has a resolution of 18 bits or better.
  - 6. Apparatus according to claim 1, wherein the signal processor unit comprises one or more processing devices from a group consisting of ASICs (Application Specific Integrated Circuits), gate arrays, FPGAs (Field Programmable Gate Arrays) and analogue processor chips.
  - 7. Apparatus according to claim 1, wherein the signal processor unit comprises a modulation unit for enabling a change in the intensity of the laser output light according to a predefined pattern or according to algorithmic calculations.
  - 24. Apparatus according to claim 1, comprising electronics modules associated with said optical source and said optical detection unit, respectively, said optical source being arranged as part of a transmitter module and said optical detection unit being arranged as part of a receiver module, said transmitter and receiver modules being arranged at spaced apart positions and interconnected by digital communication means.
  - 25. Apparatus according to claim 24, wherein the digital communication means comprises at least one optical fiber between digital electronics modules in said transmitter and in said receiver, respectively.
  - 26. Apparatus according to claim 24, wherein the digital communication means comprises at least one electrically conducting wire between digital electronics modules in said transmitter and in said receiver, respectively.

8. Gas monitor comprising, a tunable laser diode source, an optical detector, whereby said source and said detector are arranged so that light from the laser diode propagates through a gas measurement volume prior to being received by the optical detector an integrated circuit (IC) for controlling said tunable laser diode and for processing signals provided by said optical detector, said IC being adapted to provide, at an output port, a digital output signal for control of the laser diode, and said IC being adapted to receive, at an input port, a second digital input signal representing a detection signal provided by the detector, the IC being further adapted to calculate a digital value representing a gas concentration in the gas measurement volume, and wherein a digital-to-analogue (D/A) converter is connected with its input to said output port of the IC and its output is connected directly to said tunable optical source, and an analogue-to-digital (A/D) converter is connected with its input to the output of the optical detector and with its output to said input port of the IC.

9. Gas monitor comprising, a tunable diode laser source, a light sensitive detector, the source and the detector being arranged so that light from the source propagates through a gas measurement volume prior to being received by the detector, wherein a custom hardware logic circuit is provided for control and modulation of the source and processing of the detected signal and for calculating a digital value representing a gas concentration in the gas measurement volume, and said custom hardware logic circuit is coupled to the said source using a digital-to-analogue (D/A) converter, and the detector output signal is coupled to the input of an analogue-to-digital (A/D) converter, and the output of the said A/D converter is coupled to said custom hardware logic circuit.
- View Dependent Claims (10, 11)
- - 10. Gas monitor according to claim 9, wherein a microprocessor is embedded in an integrated circuit together with said custom hardware logic circuit.
  - 11. Gas monitor according to claim 9, wherein a microprocessor in the form of an auxiliary integrated circuit, is arranged separately from said custom hardware logic circuit for assisting the control and processing functionality of the gas monitor.

12. Gas monitoring apparatus, in particular for safety and alarm purposes, based on optical spectroscopy for the detection of a possible first gas i.e. H2S and a possible second gas i.e. CH4, in a gas measurement volume, comprising an optical source including one tunable diode laser, an optical detection unit including one light detector, said source and said detector being arranged so that light from the source propagates through said volume before falling on said detector, wherein said diode laser is adapted to scan an absorption line of said first gas and an absorption line of said second gas in a single or double wavelength scan comprising wavelengths in the range from 1590 to 1610 nm, and a control and processing unit is provided for the control and modulation of the source and processing of a detected signal from said detector and for calculating digital values representing the concentration of said first gas and said second gas, respectively, in the gas measurement volume.
- View Dependent Claims (14, 27, 28)
- - 14. Apparatus according to claim 12, wherein the control and processing unit is adapted to perform essentially digital signal processing, and to calculate at least one digital value taking into account the amplitude and the width of each gas absorption line detected.
  - 27. Apparatus according to claim 12, wherein the tunable laser diode is a DFB-type or VCSEL-type laser.
  - 28. Apparatus according to claim 12, wherein said diode laser additionally is adapted to scan an absorption line of a third gas, e.g. CO₂, that is normally present in the gas measurement volume, whereby three gas absorption lines are scanned in the same scan.

13. Gas monitoring apparatus based on optical spectroscopy for the detection of a possible first gas and a second gas being normally present in a gas measurement volume, comprising an optical source including one tunable diode laser, an optical detection unit including one light detector, said source and said detector being arranged so that light from the source propagates through said volume before falling on said detector, wherein said diode laser is adapted to scan an absorption line of said first gas and an absorption line of said second gas in a single or double wavelength scan, a control and processing unit is provided for the control and modulation of the source and processing of a detected signal from said detector and for calculating digital values representing the concentration of said first gas and said second gas, respectively, in the gas measurement volume, and non-spectroscopic means is provided for measurement of said second gas, thereby verifying the spectroscopic measurement of the second gas.

15. Gas monitoring apparatus based on optical spectroscopy for the detection of a possible first gas and a second gas being normally present in a gas measurement volume, comprising an optical source including one tunable diode laser, an optical detection unit including one light detector, said source and said detector being arranged so that light from the source propagates through said volume before falling on said detector, wherein said diode laser is adapted to scan an absorption line of said first gas and an absorption line of said second gas in a single or double wavelength scan, a control and processing unit is provided for the control and modulation of the source and processing of a detected signal from said detector and for calculating digital values representing the concentration of said first gas and said second gas, respectively, in the gas measurement volume, and means is provided for utilizing one of said digital values related to said second gas, to provide tracking signals for the tunable diode laser, thus to avoid wavelength drift thereof.
- View Dependent Claims (17)
- - 17. Apparatus according to claim 15, wherein the control and processing unit is adapted to perform essentially digital signal processing, and to calculate at least one digital value taking into account the amplitude and the width of each gas absorption line detected.

16. Gas measurement apparatus based on optical spectroscopy for measuring the temperature and concentration of oxygen in a gas volume, comprising an optical source including one tunable diode laser, an optical detection unit including one light detector, said source and said detector being arranged so that light from the source propagates through said volume before falling on said detector, wherein said tunable diode laser is adapted to scan across at least two absorption lines of the oxygen gas in the wavelength range from 760.04 to 760.10 nm, and a control and processing unit is provided for the control and modulation of the source and processing of a detected signal from said detector and for calculating digital values representing said oxygen concentration and temperature.
- View Dependent Claims (18, 19, 20, 21, 22, 23)
- - 18. Apparatus according to claim 16, where said tunable diode laser is adapted to scan across an absorption line pair at wavelengths of 760.096 nm and 760.069 nm, respectively, for low temperature measurement of oxygen and temperature.
  - 19. Apparatus according to claim 16, where said tunable diode laser is adapted to scan across an absorption line pair at wavelengths of 760.043 nm and 760.048 nm, respectively, for very high temperature measurement of oxygen and temperature.
  - 20. Apparatus according to claim 16, where said tunable diode laser is adapted to scan across an absorption line pair at wavelengths of 760.096 nm and 760.048 nm, respectively, for high temperature measurement of oxygen and temperature.
  - 21. Apparatus according to claim 16, where said tunable diode laser is adapted to scan across an absorption line pair at wavelengths of 760.096 nm and 760.043 nm, respectively, for high temperature measurement of oxygen and temperature.
  - 22. Apparatus according to claim 16, where said tunable diode laser is adapted to scan across an absorption line pair at wavelengths of 760.069 nm and 760.048 nm, respectively, for high temperature measurement of oxygen and temperature.
  - 23. Apparatus according to claim 16, where said tunable diode laser is adapted to scan across an absorption line pair at wavelengths of 760.069 nm and 760.043 nm, respectively, for high temperature measurement of oxygen and temperature.

29. Method for gas detection in a measurement volume, comprising the steps of launching light into said measurement volume using a tunable diode laser source, detecting and converting a part of the light from said source having propagated through a part of the measurement volume into an electronic signal using an optoelectronic detector, converting said electronic signal into a digital signal using an analogue-to-digital (A/D) converter, processing said digital signal into a signal representative of gas characteristics of said measurement volume using a signal processor unit, and determining said representative signal at least in part on the basis of the amplitude and the width of each absorption line detected in the gas.
- View Dependent Claims (31, 32, 33, 34)
- - 31. Method according to claim 29, wherein wavelength scanning of said tunable diode laser is performed across at least two absorption lines for at least two different gases.
  - 32. Method according to claim 31, wherein said scanning is performed across at least two absorption lines for methane (C4H) and hydrogen sulphide (H2S), preferably in the range of 1590 to 1610 nm.
  - 33. Method according to claim 29, wherein normally present in the measurement volume, whereby tracking, adjustment or calibration of said tunable diode laser and/or said processing unit is made possible.
  - 34. Method according to claim 29, wherein wavelength scanning of said tunable diode laser is performed across three absorption lines for three different gases, two of said three gases being preferably methane (C4H) and hydrogen sulphide (H2S), a third gas being a type of gas that is normally present in the measurement volume.

30. Method for gas detection in a measurement volume comprising, the steps of providing a modulation and control signal to a tunable diode laser source using a control and signal processing unit and a digital-to-analogue converter, directing light from said laser source into the measurement volume, detecting and converting into an electronic signal a part of the light from said source using a light sensitive detector, said part having propagated through a part of said measurement volume providing a digital representation of said electronic signal to said control and signal processing unit using an analogue-to-digital (A/D) converter, processing said digital representation in the control and signal processing unit in order to generate digital code representing at least one value related to the gas fraction contents of said measurement volume, and said at least one value being determined at least in part on the basis of the amplitude and the width of each absorption line detected in the gas.

35. Gas detection apparatus comprising, an optical source unit including a tuneable diode laser, an optical detection unit including a light sensitive detector, the source and the detector being arranged so that light from the source propagates, through a gas measurement volume prior to being received by the detector, and the source being adapted to scan the light wavelength across one or more expected absorption lines of gases in the measurement volume, a control and processing unit for control and modulation of the source and processing of the detected signal and for calculating at least one digital value representing gas concentrations in the gas measurement volume, wherein said control and processing unit is coupled to the source via a digital-to-analogue (D/A) converter, and the detector output signal is coupled to the input of an analogue-to-digital (A/D) converter, and the output of the A/D converter is coupled to the processing unit, and the control and processing unit is adapted to perform essentially digital signal processing, a first step of calculation being convolution with a suitable convolution function to remove the DC-level, suppress noise and to enhance each gas absorption line a second step being to convert the peak value of each absorption line into a gas concentration.

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Current Assignee
Norsk Elektro Optikk AS
Original Assignee
Norsk Elektro Optikk AS
Inventors
Torring, Havard, Hagene, Jon Kristian, Bjoroy, Ove, Avetisov, Viacheslav

Application Number

US10/925,146
Publication Number

US 20060044562A1
Time in Patent Office

Days
Field of Search
US Class Current

356/437
CPC Class Codes

G01N 2021/151   Gas blown

G01N 21/031   Multipass arrangements

G01N 21/39   using tunable lasers

Gas monitor

First Claim

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Abstract

93 Citations

35 Claims

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Gas monitor

First Claim

1 Assignment

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0 Petitions

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Abstract

93 Citations

35 Claims

Specification

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Use Cases

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Others