The invention is generally related to a lidar system (i.e., laser radar system), and more particularly, using wavelength division multiplexing filters in a chirped, frequency-modulated continuous-wave (“FMCW”) lidar system.
Various conventional lidar systems (i.e., laser radar systems) employ coherent detection, in which a received optical signal is combined with a mixing or reference optical signal to produce an interference signal. Conventional chirped lidar systems typically maintain a separate optical path for each of two or more chirped signals up until such signals are transmitted to a target. Similarly, conventional chirped lidar systems also typically maintain a separate optical path for each of one or more received signals reflected from the target to combine such received signals with separate mixing reference signals. As such, conventional chirped lidar systems typically employ a significant number of optical components and optical fibers.
What is needed is a chirped lidar system that employs fewer optical components and fewer lengths of optical fibers.
According to various implementations of the invention, a lidar utilizes wave division multiplexing to reduce an overall number of required optical components. In some implementations of the invention, such a lidar includes a first laser source configured to generate a first laser output at a first frequency and a second laser source configured to generate a second laser output at a second frequency, wherein the first frequency is different from the second frequency. In some implementations of the invention, the lidar includes a combining coupler, which combines the first laser output and the second laser output into a combined output. In some implementations of the invention, the combined output is carried by an optical fiber to its fiber tip where the combined output is transmitted as a transmit signal toward a target. In some implementations of the invention, a reflected portion of the transmit signal reflected back from a point on the target is received. In some implementations of the invention, the lidar includes a mixing coupler, which mixes the received reflected portion of the transmit signal with a second portion of the combined output and outputs a mixed signal. In some implementations of the invention, the lidar includes a wavelength filter, which separates the mixed signal into a first mixed signal corresponding to the first frequency of the first laser source and a second mixed signal corresponding to the second frequency of the second laser source. In some implementations of the invention, the lidar includes a first detector that detects the first mixed signal, and a second detector that detects the second mixed signal. In some implementations of the invention, the lidar uses the two detected mixed signals to determine both a range and a Doppler velocity of the point on the target.
These implementations, their features and other aspects of the invention are described in further detail below.
Conventional chirped lidar systems employ two or more laser sources to provide chirped lidar signals. These chirped lidar signals, when incident upon and reflected back from a point on a target, may be detected and used to determine a range and an instantaneous Doppler velocity of the point on the target. Such a lidar system is described in U.S. Pat. No. 7,511,824, entitled “Chirped Coherent Laser Radar System and Method,” which issued on Mar. 31, 2009, and which is assigned to Digital Signal Corporation of Chantilly, Va. The foregoing patent is incorporated herein by reference as if reproduced below in its entirety.
In some implementations of the invention, lidar optical path 105 includes a combining coupler 120. In some implementations of the invention, combining coupler 120 may be an optical device that combines two input light paths into at least one output light path. In some implementations of the invention, some combining couplers described herein may be fiber-optic devices as would be appreciated. In some implementations of the invention, some combining couplers may be fiber-optic fusion combining couplers or wavelength filters as would be appreciated. In some implementations of the invention, some combining couplers may be micro-optic devices as would be appreciated. Combining coupler 120 receives first chirped lidar signal 112A and second chirped lidar signal 112B and combines them to output a combined lidar signal 122 and a reference signal 123 (sometimes also referred to as a mixing signal or local oscillator signal as would be appreciated).
In some implementations of the invention, lidar optical path 105 includes a separator 130. In some implementations of the invention, separator 130 may be an optical device that splits an input light path into two output light paths, each at a predetermined power ratio relative to the input light path. In some implementations of the invention, some separators described herein may be fiber-optic devices as would be appreciated. In some implementations of the invention, some separators may be fiber-optic fusion separators as would be appreciated. In some implementations of the invention, some separators may be micro-optic devices as would be appreciated. Separator 130 allows a portion of combined lidar signal 122 to propagate to fiber tip 135 as a transmit signal 132 and to be transmitted toward target 150. In some implementations of the invention, a portion of transmit signal 132 is incident upon and reflected back from target 150 and returned to fiber tip 135 and propagates back to separator 130 as a returned signal 134. In some implementations of the invention, separator 130 separates a portion of the returned signal 134 from transmit signal 132 and outputs this portion as a received signal 136. Separator 130 ensures that received signal 136 does not include significant amounts of transmit signal 132 such that transmit signal 132 and receive signal 134 do not interfere (or have minimal interference) with one another. In some implementations of the invention, this arrangement facilitates uses of a same length of optical fiber to carry both transmit signal 132 and returned signal 134 from separator 130 to fiber tip 135. Separator 130 may be implemented for example as a fiber-optic splitter, as a circulator or, if the receive signal returns in a polarization orthogonal to the transmit signal, as a polarizing beam splitter. In
In some implementations of the invention, a portion of transmit signal 132 is incident upon and reflected back from target 150 and returned to a tip of a separate fiber (not otherwise illustrated) as used by a bi-static lidar, thereby eliminating the need for separator 130 as would be appreciated. Such implementations of the invention may utilize a dual-core optical fiber or fusion-tapered combination of two fibers or other two fiber implementations as would be appreciated.
As discussed above, separator 130 outputs received signal 136 which is a version of received signal 134 from fiber tip 135 after encountering some insertion loss by separator 130. In some implementations of the invention, optical path 105 includes a mixing coupler 155. Mixing coupler 155 mixes received signal 136 with a delayed version of reference signal 123. As would be appreciated, in some implementations of the invention, reference signal 123 is delayed by a delay line 125 corresponding to an expected roundtrip time of combined lidar signal 122 through separating splitter 130, to target 150 and back through separator 130 and to mixing coupler 155. In some implementations of the invention, delay 125 may be absent or differ significantly from the roundtrip delay described above as would be appreciated. Mixing coupler 155 outputs a mixed signal 157.
In some implementations of the invention, optical path 105 includes a wavelength filter 160. Wavelength filter 160 receives mixed signal 157 and separates it into two output signals 162 (illustrated in
In some implementations of the invention such as that illustrated in
In some implementations of the invention, optical path 105 includes a pair of detectors 165 (illustrated in
In some implementations of the invention, optical path 105 may include one or more attenuators (not otherwise illustrated) to reduce a power level output from fiber tip 135 to provide certain levels of safety (e.g., eye safety, etc.) or to reduce a power level of the reference signal as would be appreciated.
One benefit of lidar system 100 is a reduced number of optical components in comparison to conventional lidar systems. In some implementations of the invention, lidar system 100 utilizes roughly one-half of the number of optical components utilized by conventional lidar systems. In addition, lidar system 100 requires fewer lengths of optical fiber. This is due to the sharing of much of optical path 105 by two signals of differing wavelength, in particular delay 125 and mixing coupler 155. In some implementations of the invention, the lidar system may use multiple beams and multiple fiber tips to obtain multiple simultaneous measurements of range and Doppler velocity from separate points of the target. In such lidar systems with multiple beams, more splitters and combining couplers are used to generate the different portions of the lidar signal. Sharing the optical path by two signals of differing wavelength avoids duplication of the fiber paths and components, leading to significant savings in the required number of components and splices.
As discussed above,
In reference to
In some implementations of the invention, first 70/30 beam splitter 310A receives first lidar signal portion 122A and splits off a 30% component 312A-30. Second 70/30 beam splitter 310B receives 30% component 312A-30 from first 70/30 beam splitter 310A and splits it into two components: a 70% component 312B-70 and a 30% component 312B-30.
In some implementations of the invention, third 70/30 beam splitter 310C receives second lidar signal portion 122B and splits it into two components: a 70% component 312C-70 and a 30% component 312C-30. Fourth 70/30 beam splitter 310D receives 70% component 312C-70 from third 70/30 beam splitter 310C and splits off a 30% component 312D-30.
In some implementations of the invention, output multiplexer section includes two 50/50 beam splitters 320 (illustrated in
Applying beam splitters 310, 320 (and their associated split ratios) to combined lidar signal 122 through output multiplexer section 210 results in six versions of combined lidar signal 122: component 322A-1 corresponding to roughly 10.5% of the power of combined lidar signal 122; component 322A-2 corresponding to roughly 10.5% of the power of combined lidar signal 122; component 322B-1 corresponding to roughly 10.5% of the power of combined lidar signal 122; component 322B-2 corresponding to roughly 10.5% of the power of combined lidar signal 122; and component 312B-30 corresponding to roughly 9% of the power of combined lidar signal 122. As stated, four of these signals have roughly the same power level with the fifth signal having slightly less. Signal 312C-30 is a sixth version of the combined lidar signal 122 with approximately 30% of the power of the combined lidar signal 122. Signal 312C-30 is used as mixing/reference signal, routed to delay line 125 and further split into components in detector section 230.
In some implementations of the invention, output multiplexer section 210 includes five separators 330 (illustrated in
To accommodate the five transmit signals 332 and their accompanying receive signals RX1, RX2, RX3, RX4, and RX5, additional mixing couplers and wavelength filters may need to be included in lidar 100.
In some implementations of the invention, detector section 230 includes five mixing couplers 430 (illustrated in
In some implementations of the invention, mixing couplers 430 may correspond to a beam splitter with a 90/10 split ratio or any other suitable, asymmetric split ratio in order to facilitate implementation of an asymmetric single-ended detector as described in U.S. patent application Ser. No. 14/249,085, entitled “System and Method for Using Combining Couplers with Asymmetric Split Ratios in a Lidar System,” filed on Apr. 9, 2014, and which is assigned to Digital Signal Corporation of Chantilly, Va. The foregoing patent application is incorporated herein by reference as if reproduced below in its entirety.
In some implementations of the invention, detector section 230 includes five wavelength filters that separates each mixed signal 432 into separate components based on the wavelengths of laser sources 110 as discussed above. In some implementations, as discussed above with regard to
As illustrated in
In some implementations of the invention, detector section 230 includes five pairs of detectors 465 (illustrated in
Combining coupler 120 receives first chirped lidar signal 112A and second chirped lidar signal 112B and combines them as would be appreciated. Combining coupler 120 outputs a combined lidar signal 122 in the form of two components, 122A and 122B, of about equal power, both including about equal amounts of first chirped lidar signal 112A and second chirped lidar signal 112B.
The various implementations of the invention discussed above may be configured for use in a combined lidar and video system such as that described in U.S. Pat. No. 8,717,545 entitled “System and Method for Generating Three Dimensional Images using Lidar and Video Measurements,” which issued on May 6, 2014, (the “'545 patent”) and which is assigned to Digital Signal Corporation of Chantilly, Va. The foregoing patent is incorporated herein by reference as if reproduced below in its entirety. In some implementations of the invention, transmit signals 332A-D correspond to four beams used to scan targets as described in the '545 patent and transmit signal 332E corresponds to an overscan beam as described in the '545 patent.
While the invention has been described herein in terms of various implementations, it is not so limited and is limited only by the scope of the following claims, as would be apparent to one skilled in the art. These and other implementations of the invention will become apparent upon consideration of the disclosure provided above and the accompanying figures. In addition, various components and features described with respect to one implementation of the invention may be used in other implementations as well.
This application is a continuation of U.S. application Ser. No. 16/906,018, which was filed on Jun. 19, 2020, and entitled “System and Method for an Improved Chirped Lidar;” which in turn is a continuation of U.S. application Ser. No. 15/405,411, which was filed on Jan. 13, 2017, and entitled “System and Method for an Improved Chirped Lidar;” which in turn claims priority to U.S. Provisional Application No. 62/279,083, which was filed on Jan. 15, 2016, and entitled “System and Method for an Improved Chirped Lidar.” Each of the foregoing applications is incorporated herein by reference in its entirety.
Number | Date | Country | |
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62279083 | Jan 2016 | US |
Number | Date | Country | |
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Parent | 16906018 | Jun 2020 | US |
Child | 17164581 | US | |
Parent | 15405411 | Jan 2017 | US |
Child | 16906018 | US |