Patent Application
20100220331
Devices may sense the presence (or absence) of particular molecules. For example, a miniature or hand-held spectrometer might be used to detect biological, chemical, and/or gas molecules. Such devices might be useful, for example, in the medical, pharmaceutical, and/or security fields. By way of example, a hand-held device might be provided to detect the presence of explosive materials at an airport.
In some sensing devices, light reflected from a sample of molecules is analyzed to determine whether or not a particular molecule is present. For example, the amount of light reflected at various wavelengths might be measured and compared to a known “signature” of values associated with that molecule. When the reflected light matches the signature, it can be determined that the sample includes that molecule.
In some sensing devices, a Fabry-Perot filter such as the one illustrated in
As the photons bounce within the cavity C, interference occurs and an interference pattern is produced in light exiting the filter 100. As a result, light having a specific wavelength may exit the filter 100. Note that the interference occurring within the cavity C is associated with the distance d between the two mirrors 110, 120. Thus, the filter 100 may be “tuned” to output a particular wavelength of light by varying the distance d between the mirrors 110, 120 (e.g., by moving at least one of the mirrors 110, 120).
In some cases, one of the mirrors is formed using a diaphragm that can be flexed to change the distance d. For example,
Such an approach, however, may have disadvantages. For example, the curving of the flexible diaphragm mirror 210 may limit its usefulness as a Fabry-Perot mirror. Moreover, the use of a flexible diaphragm mirror 210 may introduce stress over time and lead to failures. The design might also require bonding materials together that have different thermal characteristics—which can lead to problems at relatively high, low, or dynamic temperature environments. In addition, as the size of the cavity C is reduced, it can be difficult to efficiently control the movement of the flexible diaphragm mirror 210. Note that the use of piezoelectric elements to move mirrors arranged as in
According to some embodiments, a micro-electrical mechanical system apparatus includes an actuator within a plane and at least one movable mirror oriented substantially normal to the plane. The actuator may move the movable mirror with respect to a fixed mirror oriented substantially normal to the plane and substantially parallel to the movable mirror. The space between the fixed and movable mirrors might comprise, for example, a Fabry-Perot filter cavity for a spectrometer.
Some embodiments comprise: means for routing light from a sample of molecules into a tunable Fabry-Perot cavity; means for scanning a first partially transmitting mirror of the cavity through a range of positions relative to a second partially transmitting mirror of the cavity, wherein the first and second mirrors are (i) substantially parallel to each other and (ii) substantially normal to a plane defined by a wafer, such as a silicon wafer; and means for detecting an interference pattern across a spectral range of light wavelengths, wherein different portions of the spectral range are associated with different distances between the first and second mirrors.
Other embodiments may provide a spectrometer having a laser source and an analyte sample to reflect light from the laser source. A Fabry-Perot filter cavity may be provided to receive the reflected light, including: an actuator within a plane; at least one movable mirror oriented substantially normal to the plane, wherein the actuator is to move the movable mirror; and a fixed mirror oriented substantially normal to the plane and substantially parallel to the movable mirror. In addition, a detector may be provided to detect photons exiting the Fabry-Perot filter cavity over time as the movable mirror is moved by the actuator. According to some embodiments, a decision unit may determine if the analyte sample is associated with at least one type of molecule based on the sensed photons.
The filter 300 further includes an actuator 330 within a plane, such as a plane defined by a surface of a silicon wafer. Note that the movable and/or fixed mirrors 310, 320 may be oriented substantially normal to that plane (e.g., vertically within the wafer).
According to some embodiments, the actuator 330 is coupled to the movable mirror 310 via an attachment portion 340. Moreover, the actuator 330 may move or “scan” the movable mirror 310 left and right in
As the movable mirror 310 is scanned, broadband light may enter the filter 300 (e.g., via fiber optic cable introducing the light through the fixed mirror 320) and some photons may reflect off of the fixed mirror 310 while others pass through the mirror 310 and enter the cavity C. While in the cavity C, the photons may reflect between the fixed and movable mirrors 310, 320, and eventually some of the photons may pass through the movable mirror 320 and exit the filter 300.
As a result, the filter 300 may act as a narrow-band optical filter and the wavelength of light that exits the filter may vary over time (as d is varied). That is, the wavelength of light output from the filter 300 will scan back and forth across a range of the optical spectrum over time. By measuring the intensity of the light at various times (and, therefore, various distances d and wavelengths), information about the light entering the filter can be determined.
Although a single pair of mirrors 310, 320 are illustrated in
The actuator 330 may be any element capable of moving the movable mirror 310. Note that, unlike the flexible diaphragm approach described with respect to
According to some embodiments, the actuator 330 may be a bi-stable structure. In this case, the actuator 330 may be snapped between the two stable positions to scan the filter 300. The actuator 330 might be associated with, for example, a thermal device, an electrostatic device, and/or a magnetic device. According to some embodiments, a spring may be coupled to the movable mirror 310 and/or actuator 330 to improve control.
The Fabry-Perot filter 300 may be associated with, for example, a spectrometer.
According to this embodiment, the spectrometer 400 includes a light source 410 (e.g., a laser associated with λL) that provides a beam of light to an analyte sample 420. Photons are reflected off of the analyte sample 420 and pass through the Fabry-Perot filter 300 as described, for example, with respect to
Because the Fabry-Perot filter 300 is scanning di over time, a detector 400 may measure light having varying wavelengths λL over time. These values may be provided to a decision unit 450 that compares the values with a signature of a known molecule (or sets of molecules) signatures. Based on the comparison, the decision unit 450 may output a result (e.g., indicating whether or not any of the signatures were detected).
At Step 504, a first partially transmitting mirror of the cavity is scanned through a range of positions relative to a second partially transmitting mirror of the cavity. According to some embodiments, the first and second mirrors are (i) substantially parallel to each other and (ii) substantially normal to a plane defined by a silicon wafer. Note that the scanning might be performed by an actuator within the plane defined by the silicon wafer.
At Step 506, an interference pattern is detected across a spectral range of light wavelengths. Note that different portions of the spectral range may be associated with different distances between the first and second mirrors. The detected interference pattern may then be compared with a signature pattern associated with a particular molecule, and an indication may be provided based on the comparison.
Note that different types of actuators may be used to move a movable mirror in a Fabry-Perot filter, including parallel plate drives and/or comb drives.
According to some embodiments, a movable or fixed mirror may be associated with a crystallographic plane of silicon and a Fabry-Perot filter may be associated with a Micro-electromechanical System (MEMS) device. For example,
Although the mirrors 710, 720 illustrated in
The following illustrates various additional embodiments of the invention. These do not constitute a definition of all possible embodiments, and those skilled in the art will understand that the present invention is applicable to many other embodiments. Further, although the following embodiments are briefly described for clarity, those skilled in the art will understand how to make any changes, if necessary, to the above-described apparatus and methods to accommodate these and other embodiments and applications.
Although a single movable mirror has been provided in some embodiments described herein, note that both mirrors associated with a Fabry-Perot cavity might be movable (and each mirror might be simultaneously moved with respect to the other mirror).
Further, although particular layouts and manufacturing techniques have been described herein, embodiments may be associated with other layouts and/or manufacturing techniques. For example, cap wafers with optical and/or electrical ports may be provided for any of the embodiments described herein. Such wafers may, for example, be used to interface with an Application Specific Integrated Circuit (ASIC) device.
Moreover, although Fabry-Perot filter designs have been described with respect to spectrometers, note that such filters may be used with any other types of devices, including telecommunication devices, meteorology devices, and/or pressure sensors.
The present invention has been described in terms of several embodiments solely for the purpose of illustration. Persons skilled in the art will recognize from this description that the invention is not limited to the embodiments described, but may be practiced with modifications and alterations limited only by the spirit and scope of the appended claims.
