1. Field
The present invention relates generally to systems and methods for locating gunshots and similar explosive acoustic events. More specifically, it relates to real-time gunshot location systems using a network of acoustic sensors distributed throughout a geographical region.
2. Description of Related Information
Gunshot location systems have been used in various municipalities to assist law enforcement agencies in quickly detecting and responding to incidents of urban gunfire. The details of two such gunshot location systems are described in U.S. Pat. No. 5,973,998 to Showen et al. and U.S. Pat. No. 6,847,587 to Patterson et al., both of which are incorporated herein by reference. Showen's system locates gunshot events using a network of acoustic sensors with an average neighboring sensor separation of approximately 2000 feet. A computer receives acoustic signals from the sensors and triangulates a location, e.g., using relative time-of-arrival (TOA) information and/or angle-of-arrival (AOA) information of signals received from at least three sensors. A sensor may obtain an angle of arrival by measuring phase differences between very closely spaced microphones at the sensor site. Angles of arrival may be used to confirm a triangulated location by requiring a match between an intersection of angles and the triangulated location. Showen et al. also teach techniques for selecting a best triad of sensor signals to use in triangulation, e.g., selecting the triad that has the most number of confirming events from other sensors, selecting the triad that has the most widely-spread direction vectors, selecting the triad that has the largest total signal sharpness (or impulsiveness), and selecting the triad that gives the most central location among other candidate locations from other triads.
In complex urban environments, acoustic signals often experience reflections, refraction, and complete blockage from buildings and other objects, resulting in missing or misleading signals at sensors. Additionally, short-range signals like hammering can produce confusion. Consequently, in such environments it can be difficult to triangulate gunshot locations with accuracy and confidence. There thus remains a need to provide improved gunshot location systems that meet these challenges.
The present invention provides a gunshot location system that uses angular information together with TOA information from a collection of sensors to compute candidate gunshot locations. The sensors include one or more azimuthal sensors which provide angular information (e.g., AOA or information from which AOA may be derived). In preferred embodiments, the azimuthal sensor can also provide an angular uncertainty (i.e., beam width). Use of this enhanced AOA information permits more sophisticated and reliable determination of candidate gunshot locations.
In a preferred embodiment, each azimuthal sensor has four or more microphones equally spaced on a circumference of a circle. The sensor or other processor can determine from the four impulse arrival times a mean angle and standard deviation associated with the angle, both of which may be calculated from combinations of impulse arrival times from different triads of the four or more microphones. Preferably, the enhanced AOA information is computed by the azimuthal sensors and sent from the sensors via communication links to a computer which calculates the candidate gunshot locations. Alternatively, the sensors may send AOA information in the form of impulse arrival times to the computer which then calculates the angle of arrival.
The system includes first and second acoustic sensors, each communicating TOA information derived from acoustic impulses sensed at the sensor. At least one sensor also communicates enhanced AOA information derived from acoustic impulses sensed at the sensor, e.g., an azimuthal angle value and an angular uncertainty value or timing information from which these values may be derived. The computer receives the TOA information from the first and second acoustic sensors and computes a hyperbola consistent with the TOA information from the two sensors. The computer also receives the AOA information from at least one of the acoustic sensors and computes an angular beam consistent with the enhanced AOA information. An intersection of the hyperbola and the angular beam is then determined, and a candidate gunshot location within the intersection is computed.
In preferred implementations, both TOA and AOA information is provided from at least two sensors. By combining enhanced AOA information with TOA information from two sensors, the second beam may be used to confirm a location determined from the first beam and hyperbola. Thus, candidate locations may be confirmed with just two sensors. This is a significant improvement over prior systems without azimuthal sensors which required four sensors to locate and confirm a gunshot event.
AOA and/or TOA information from additional acoustic sensors may be included to further improve accuracy and/or confidence in the candidate location. Consequently, the present system provides improved performance in complex acoustic environments. Alternatively, the sensor spacing may be increased if the environment is not acoustically complex, reducing the required sensor density and decreasing the expense of deploying a network of sensors over a defined coverage area. In implementations of the system where to the sensors are positioned next to a roadway in an approximately linear arrangement, the use of the AOA information together with the TOA information allows the nearest neighbor distance between sensors to be increased to approximately 75% to 100% of the maximum range of sensor detectability.
Methods for calculating candidate gunshot locations may use enhanced AOA information from one or more sensors in various ways to improve system performance. For example, AOA information from one sensor in the collection of acoustic sensors may be used to disregard TOA information from that sensor if the AOA information is inconsistent with the location of an event determined from other sensors, which implies the signal arriving at the sensor was probably reflected. Alternatively, AOA information may be used to resolve an ambiguity in candidate locations computed when a detection using three sensors gives two mathematically valid triangulations.
In complex acoustic environments (e.g., involving blocked and reflecting paths plus additional short-range interfering signals), both TOA and AOA information provided from four or more sensors may be combined to select among various candidate gunshot locations. For example, for each of the candidate gunshot locations, the number of consistent TOA impulses and AOA directions received from the collection of acoustic sensors may be counted. The candidate gunshot locations can then be prioritized based on the counted impulses or directions, with highest priority given to the location with the largest number of consistent counts. With the addition of AOA information, either the number of redundant acoustic paths needed to decide between alternative location solutions can be reduced or the certainty of selection with the same number of paths can be improved.
A gunshot location system according to a preferred embodiment of the invention is shown in
An exemplary gunshot event 116 generates an acoustic impulse that radiates outward from its originating location. At time t1, the impulse has position 118 and is sensed by sensor 100. At a later time t2, the impulse has position 120 and is sensed by sensor 102. Computer 114 receives TOA information t1 and t2 from sensors 100 and 102 and is able to compute a time difference Δt between times t1 and t2.
An acoustic sensor according to a preferred embodiment of the invention is shown in
Although only three microphones are required to compute a horizontal angle of arrival, sensor 200 preferably contains four or more microphones which enables the sensor to include an angular uncertainty value with the AOA information. An acoustic impulse derived from a single gunshot event has an angle of arrival φ at the sensor. Because the spacing between the microphones (typically less than one foot) is much smaller than the distance from the sensor to the gunshot (typically hundreds or thousands of feet), the acoustic impulse is well-approximated as a plane wave. In the example shown, the acoustic impulse is first sensed by microphone 204 when the impulse wave front is in position 214 at time τ1. At time τ2, the impulse wave front has position 216 and is sensed by microphone 202. Processor 210 receives acoustic impulse signals from the microphones and determines impulse arrival times τ1 and τ2. Similarly, impulse arrival times are also determined from signals received from microphones 206 and 208. A graph of the four signals 222, 224, 226, 228 received at processor 210 from microphones 204, 202, 208, 206, respectively, is shown in
The four microphones have predetermined fixed positions within the sensor in a horizontal plane, and the sensor is oriented at a predetermined angle. Thus, processor 210 is able to compute the angle φ220 toward the source of the impulse relative to a reference orientation line 218 of the sensor. The orientation line 218 is predetermined and fixed upon installation or may be determined in real time from a compass, GPS receiver, or other similar means. According to one embodiment, processor 210 computes four angles of arrival, each using the signals from a different triad of sensors. The azimuth angle φ is the mean of the four angles, while the angular uncertainty is the standard deviation of the four angles. According to another embodiment, a matrix inversion technique with inputs from all microphones is used to calculate the most consistent input angle assuming a plane wave. A further method is to cross-correlate each microphone signal against the signal from the reference microphone signal and use the maximum value of the cross-correlation to determine the time offsets. Yet another method is to cross-correlate each signal against a synthetic signal (not from any of the microphones). An advantage here is that there is less susceptibility to common-mode noise (e.g., loud 60 Hz noise from a nearby transformer).
These techniques easily generalize to embodiments in which more than four microphones are used to provide more precision in the angle measurement. The sensor microphones are preferably positioned so that they are equally spaced on a circumference of a circle. In the case of four sensors, this is equivalent to positioning the sensors at the corners of a square. More generally, the sensors are positioned isotropically in a rotationally symmetric arrangement, i.e., at the vertices of a regular polygon. This rotationally symmetric arrangement of the microphones has the advantage that calculations of the AOA information are independent of variations in ambient temperature (which affect the to speed of sound).
In an alternate embodiment, some or all of the computations performed by processor 210 as described above may instead be performed by at computer 114 (
In addition, TOA information provided by the sensors also may include temporal uncertainty caused by refraction of the impulses during propagation, resulting in a width 316 of TOA hyperbola 312. From experimentation, typical suburban environments will produce temporal propagation errors averaging approximately 20 feet. Urban environments with buildings having more than two stories will have larger average errors. Thus, the TOA information also defines a two-dimensional region rather than a one-dimensional curve. The intersection of multiple two-dimensional regions typically results in smaller two-dimensional regions, providing increased accuracy as more information is available. The intersection of multiple one-dimensional curves, in contrast, is overly restrictive in many cases and results in a null set.
An alternative method to calculate the position of a source using two or more azimuthal sensors (as was illustrated in
Urban environments often contain buildings and other objects that can block and/or reflect acoustic impulses as they propagate from a source to the sensors. Consequently, sensors detecting reflected impulses will report incorrect AOA and TOA information. For example,
AOA information may be used to resolve an ambiguity arising from multiple solutions to the intersection of TOA hyperbolas, as illustrated in
As discussed earlier, complex environments may contain buildings that block and/or reflect acoustic impulses and cause sensors to provide misleading information. In addition, complex environments may also contain interfering impulsive events other than gunshots (e.g., hammer strikes and bouncing basketballs). AOA information can be effectively combined with TOA information in such environments to improve the probability of correctly locating gunshots. For example,
In situations such as that shown in
After the events for each sensor are counted, candidate gunshot locations can then be prioritized based on the counted events, with highest priority given to the location with the largest number of votes. In the example shown, the actual location 624 obtained seven votes, while the candidate location 628 obtained only four. Consequently, location 624 is selected. This vote-counting method has the advantage that it may be applied generally to complex situations with unknown reflections, blocking, and false impulses detected by four or more sensors. A refinement of this scheme would allow the number of votes accorded to each AOA or TOA datum to be weighted by the reliability of the measurement. The more sensors with signals available to give more redundant paths and azimuths the better, up to a point where the sensors are so close together that a weak (non-gunfire) source can register on two sensors, in which case the benefit of a spatial filter is not achieved.
All prior discussions have concerned coverage over an area. Another benefit of the present invention is where a substantially linear coverage as along a highway is desired. In the context of the present disclosure, a “substantially linear” arrangement of sensors is used to mean a sequential arrangement of sensors where the triangle formed by connecting a sequence of three adjacent sensors has a smallest angle no larger than 30 degrees. For example,
This is a continuation of application Ser. No. 12/172,163, filed Jul. 11, 2008, published as US2008/0279046A1, now U.S. Pat. No. 7,599,252, which is a continuation of application Ser. No. 11/546,529, filed Oct. 10, 2006, published as US2008/0084788A1, now U.S. Pat. No. 7,474,589, which are incorporated herein by reference in entirety.
Number | Date | Country | |
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Parent | 12172163 | Jul 2008 | US |
Child | 12573775 | US | |
Parent | 11546529 | Oct 2006 | US |
Child | 12172163 | US |