Source: https://patents.google.com/patent/JP3910629B2/en
Timestamp: 2019-12-08 06:27:38
Document Index: 246176203

Matched Legal Cases: ['art 180', 'art 190', 'art 110', 'art 120', 'art 121', 'art 122', 'art 130', 'art 131']

JP3910629B2 - Person determination device and person search tracking device - Google Patents
Person determination device and person search tracking device Download PDF
JP3910629B2
JP3910629B2 JP2006531421A JP2006531421A JP3910629B2 JP 3910629 B2 JP3910629 B2 JP 3910629B2 JP 2006531421 A JP2006531421 A JP 2006531421A JP 2006531421 A JP2006531421 A JP 2006531421A JP 3910629 B2 JP3910629 B2 JP 3910629B2
JP2006531421A
JPWO2006013765A1 (en
正宏 岩崎
2004-08-03 Priority to JP2004227083 priority Critical
2005-07-27 Application filed by 松下電器産業株式会社 filed Critical 松下電器産業株式会社
2005-07-27 Priority to PCT/JP2005/013769 priority patent/WO2006013765A1/en
2007-04-25 Publication of JP3910629B2 publication Critical patent/JP3910629B2/en
2008-05-01 Publication of JPWO2006013765A1 publication Critical patent/JPWO2006013765A1/en
The present invention relates to a person determination apparatus for determining whether or not persons included in different image sequences are the same person, and an apparatus for searching and tracking a person to which the person is applied.
In order to search and track a specific person from an image sequence obtained by a surveillance camera or the like, it is necessary to identify the person, that is, determine whether or not the person in different images or image sequences is the same person. Is needed.
Conventionally, as a method for determining the same person for the purpose of searching and tracking a person in an image sequence, there is a technique of associating adjacent person regions between adjacent frames (for example, see Patent Document 1).
1A to 1C are diagrams illustrating a person search / tracking method described in Patent Document 1. FIG. 1A and 1B show temporally continuous frame images obtained by photographing the same person. A frame image A10 shown in FIG. 1A shows an image of a person A11 moving in the right direction. A rectangle A12 is a circumscribed rectangle that includes a head portion and a torso portion that are detected as a region where the motion is small (person stable region) using the motion vector. Similarly, in the frame image A20 shown in FIG. 1B, the circumscribed rectangle A22 of the person stable region detected from the person A21 is indicated by a broken line. In the frame image A30 shown in FIG. 1C, circumscribed rectangles A12 and A22 of the human stable region obtained from the frame images A10 and A20 are displayed simultaneously. In this conventional method, as shown in the frame image A30, the person A11 and the person A21 are associated as the same person from the overlap of the circumscribed rectangle A12 and the circumscribed rectangle A22 and the continuity of both motion vectors, Search and track.
JP 2003-346159 A (3rd and 6th pages, FIGS. 2 and 9)
However, in the above conventional method, since people are searched from positions close to each other between frames, if the person detection fails once in a certain frame, the person in the frame before the failed frame and the person in the subsequent frame Cannot be associated with each other, and the person cannot be tracked.
In addition, it is possible to associate people between different frames using the color and image pattern of the human area with the same method, but the position change due to the movement of the person between the distant frames becomes large or the same. Even a person has a problem that association becomes difficult due to changes in orientation, posture, and illumination conditions with respect to the camera.
Therefore, when there are multiple people in the image, the person who wants to search or track can be temporarily detected behind other people or objects, or the detection of people may be temporarily When a frame that cannot be performed occurs, there is a problem that search and tracking can no longer be continued.
Accordingly, the present invention solves the above-described conventional problems, and a person determination device that can determine the same person between frames that are separated in time or between frames shot by different cameras, and its It is an object of the present invention to provide a person search / tracking apparatus that searches and tracks a person using a person determination apparatus.
In order to achieve the above object, a person determination device according to the present invention is a person determination device that determines whether or not persons included in different image sequences are the same, wherein the first image sequence and An image sequence input means for receiving an input of a second image sequence acquired at a different time or a different image sensor from the first image sequence, and a person from each of the input first and second image sequences The walking sequence extracting means for extracting the first and second walking sequences which are image sequences indicating the walking state of the person, and the extracted first and second walking sequences, respectively, Walking information extracting means for extracting first and second walking information, which is information for identifying movement, and the extracted first and second walking information. And a determination unit that determines whether or not the persons included in the first and second image sequences are the same based on a verification result by the walking information verification unit. It is characterized by that. Here, as the walking information, for example, information indicating the temporal or spatial walking cycle of the person, temporal or spatial phase information in the periodic walking motion of the person, It may be temporal or spatial positional information indicating a typical walking motion.
According to the present invention, by using spatiotemporal periodic information, spatiotemporal phase information, and spatiotemporal position information obtained from human walking, it is possible to associate human image sequences obtained from different frames or from different sensors. .
In other words, a person determination device that can determine the same person between frames that are separated in time or frames taken by different cameras, and a person who searches for and tracks a person using the person determination device A search tracking device is realized.
A person determination apparatus according to an embodiment of the present invention is a person determination apparatus that determines whether or not persons included in different image sequences are the same, wherein the first image sequence and the first image An image sequence input means for receiving an input of a second image sequence acquired at a different time or a different image sensor from the image sequence, and a walking state of the person from the input first and second image sequences, respectively. A walking sequence extracting means for extracting first and second walking sequences, which are image sequences to be shown, and the extracted first and second walking sequences, respectively, identify a periodic movement of a person walking. Walking information extracting means for extracting the first and second walking information as information, and the walking for comparing the extracted first and second walking information An information matching unit; and a determination unit that determines whether or not the persons included in the first and second image sequences are the same based on a matching result by the walking information matching unit. To do. Here, as the walking information, for example, information indicating the temporal or spatial walking cycle of the person, temporal or spatial phase information in the periodic walking motion of the person, It may be temporal or spatial positional information indicating a typical walking motion.
As a result, the same person is determined by paying attention to the walking of the person, so it is determined that the person in the close position between the frames is the same person or the same person is determined by the color and the image pattern. Even if a person who wants to search / track is temporarily behind another person or object, or even if the person cannot be detected normally temporarily due to lighting changes, etc., the same person is judged. It becomes possible. In other words, the present invention utilizes the fact that the walking characteristics such as the walking cycle and the stride are different for different people, and that the same person walks with a constant walking characteristic. The same person can be determined without depending on the position, and the same person can be determined between frames that are separated in time or between frames taken by different cameras.
In addition, the walking information collating means may determine whether a person included in the first and second image sequences is based on first and second spatiotemporal phase information included in the first and second walking information, respectively. You may make it collate walk information by comparing the time or position which becomes a predetermined walking posture. Specifically, the walking information collating unit is configured to determine the first image sequence of a person included in the first image sequence based on first spatiotemporal phase information included in the first walking information. A phase information estimator for estimating spatiotemporal phase information at a different time or position, and the first and second spatiotemporal phase information estimated by the phase information estimating means based on the first spatiotemporal phase information and the second spatiotemporal phase information A walking information collating unit that collates walking information by comparing the time or position at which a person included in the second image sequence assumes a predetermined walking posture;
Thereby, it is possible to improve the accuracy of the determination as compared with the case where it is determined whether or not the persons are the same person using only the spatiotemporal period information. For example, when two persons having the same stride and walking speed are captured in the same image sequence, the spatio-temporal period information of the two persons is the same, and thus cannot be determined. However, even if the spatiotemporal period information is the same, the spatiotemporal phase information differs if the timing or position of crossing the legs is different. Therefore, more accurate determination can be performed by using the spatiotemporal phase information.
In addition, the said walk information collating means is the said 1st and 2nd image in the same time or position based on the 1st and 2nd spatiotemporal phase information contained in the said 1st and 2nd walk information, respectively. The walking information may be collated by comparing the walking postures of the persons included in the sequence. Specifically, the walking information collating unit is configured to generate a time different from the first image sequence of a person included in the first image sequence based on phase information included in the first spatiotemporal walking information. Or based on the spatio-temporal phase information and the second spatio-temporal phase information estimated by the phase information estimation means and the phase information estimation unit for estimating spatio-temporal phase information at the position, A walking information collating unit that collates walking information by comparing walking postures of persons included in the first and second image sequences.
Further, the walking sequence is, for example, an image on a cut surface when each image sequence is cut along the time axis, and specifically, a section obtained by cutting both legs of a person included in each image sequence is a time axis. An image obtained by arranging in a row. This makes it possible to extract the walking characteristics of a person in terms of time and space.
The image sequence input means may accept input of first and second image sequences acquired by different image sensors that photograph the same place. Thus, it is possible to identify a person in different image sequences obtained by photographing the same place where the blind spot exists from different angles.
The person determination device further includes correction information storage means for storing correction information indicating a correspondence relationship between the position on the image and the position at the shooting location in each of the first and second image sequences, and the correction information. Correction means for performing a spatiotemporal correction process in the extraction of the first and second walking information by the walking information extraction means based on the correction information stored in the storage means may be provided. As a result, even when images are acquired by different image sensors, inconsistencies between images based on differences in image sensor arrangement position, shooting direction, and the like are corrected, so that person determination by different image sensors becomes possible. .
Here, the correction information may be, for example, information that specifies grid lines that two-dimensionally divide the walking surface at the shooting location at a constant distance.
In order to achieve the above object, a person search / tracking apparatus according to the present invention is a person search / tracking apparatus for searching or tracking a specific person in an image sequence in which a person is imaged. The first and second walking sequences corresponding to the first and second walking information when the first and second walking information are matched by the walking information matching means included in the person determination device. It comprises walking sequence storage means for storing them in association with each other. As a result, the identity of each walking sequence is analyzed and stored in advance, and it can be retrieved and tracked while displaying the image sequence by reading and using it when searching and tracking people. Is faster.
In order to achieve the above object, a person search / tracking apparatus according to the present invention is a person search / tracking apparatus for searching or tracking a specific person in an image sequence in which a person is imaged. Display means for displaying the first and second image sequences received by the image sequence input means provided in the person determination device, wherein the display means is a person included in the first and second image sequences. Further, highlighting is performed for distinguishing a person determined to be the same person from other persons by a determination unit included in the person determination apparatus. Thereby, even when different images are displayed at the same time, the same person can be immediately known by highlighting, and the person can be easily searched and tracked.
A person determination apparatus according to another aspect of the present invention is a person determination apparatus that determines whether or not persons included in different image sequences are the same, and includes first and second persons included in the image sequence. Walking sequence detecting means for detecting first and second walking sequences, which are image sequences showing a walking state of the person, and a first person at a time or position different from the walking sequence from the walking sequence of the first person Walking posture transition estimating means for estimating information indicating the transition of the walking posture in the periodic walking motion, information indicating the estimated walking posture transition of the first person, and the walking posture of the second person And determining means for determining consistency between the first person and the second person when the consistency with the information indicating the transition of the first person and the second person is consistent.
The present invention can be realized not only as the person determination apparatus and person search tracking apparatus as described above, but also as a person determination method and person search tracking method, or as a program for causing a computer to execute the method. Or a computer-readable recording medium on which the program is recorded.
FIG. 2 is a functional block diagram showing a configuration of person determination device 10 in the present embodiment. The person determination apparatus 10 is an apparatus that determines whether or not the persons included in different sequences are the same person by paying attention to the continuity of the person's walking sequence, and includes the walking posture detection unit 200 and the walking state estimation. Part 180 and determination part 190.
The walking posture detection unit 200 is a processing unit that detects a walking sequence including a predetermined walking posture of the first person from the moving image.
The walking state estimation unit 180 is a processing unit that estimates the walking state of the first person at a time or position different from the walking sequence (the posture transition state in the walking cycle motion) from the walking sequence of the first person. .
The determination unit 190 determines the consistency between the walking state of the first person and the walking state of the second person, and when there is consistency, the first person and the second person are the same. It is a processing part to determine.
The walking posture detection unit 200 includes an image sequence input unit 100 and a walking sequence extraction unit 110.
The walking state estimation unit 180 includes a spatiotemporal period information extraction unit 120, a spatiotemporal phase information extraction unit 121, and a spatiotemporal position information extraction unit 122.
The determination unit 190 includes a spatiotemporal period information storage unit 130, a spatiotemporal phase information storage unit 131, a spatiotemporal position information storage unit 132, a spatiotemporal period verification unit 140, a spatiotemporal phase verification unit 141, a spatiotemporal difference extraction unit 142, It consists of a coincidence determination unit 150 and a control unit 160.
Here, the walking posture detection unit 200 is an example of a walking sequence detection unit that detects a walking sequence that is an image sequence indicating a walking state of a person included in the image sequence. The walking state estimation unit 180 is an example of a walking posture transition estimation unit that estimates information indicating a transition of a walking posture in a periodic walking motion of a person at a time or position different from the walking sequence from the walking sequence. Further, the determination unit 190 determines the consistency of information indicating the transition of the walking postures of the two persons captured at different times or different image sensors, and determines whether the two persons are the same person or not. It is an example of a judgment means. The “information indicating the transition of walking posture” is information including period information and phase information described later.
The image sequence input unit 100 is an example of an image sequence input unit that receives input of first and second image sequences acquired at different times or different image sensors.
The walking sequence extraction unit 110 is an example of a walking sequence extraction unit that extracts, from the first and second image sequences, first and second walking sequences that are image sequences indicating the walking state of a person, respectively.
The spatio-temporal phase information extraction unit 121, the spatio-temporal position information extraction unit 122, and the spatio-temporal period information extraction unit 120 are information that identifies periodic movements of a person's walking from the first and second walking sequences, respectively. It is an example of the walk information extraction means which extracts the 1st and 2nd walk information which is.
The spatiotemporal phase matching unit 141, the spatiotemporal difference extracting unit 142, and the spatiotemporal period matching unit 140 are an example of a walking information matching unit that matches the extracted first and second walking information.
The coincidence determination unit 150 is an example of a determination unit that determines whether the persons included in the first and second image sequences are the same person based on the collation result.
The image sequence input unit 100 is a signal interface that acquires an image sequence from a camera or an image recording apparatus. The “image sequence” is an array in which frame images taken as shown in FIG. 3 are arranged in time order.
The walking sequence extraction unit 110 is a processing unit that extracts a walking sequence from the image sequence acquired by the image sequence input unit 100. The “walking sequence” is a sequence of walking states obtained from the walking motion area in each frame image. FIG. 4B shows an example of a walking sequence. FIG. 4A is an array in which the lower body area of a person in each frame is extracted and arranged in time order. FIG. 4B shows the sections of the frame images arranged in time order at the position of the broken line B10 in FIG. 4A. The black band in FIG. 4B shows the movement trajectory of the toes (the images of the slices that cut both legs of the person arranged on the time axis). A specific calculation method for each walking sequence will be described later.
The spatiotemporal period information extraction unit 120 is a processing unit that extracts period information of a spatiotemporal change in walking from the walking sequence extracted by the walking sequence extraction unit 110. “Periodic information” refers to the number of steps per fixed time and fixed distance, the results obtained by performing frequency analysis on the spatio-temporal position change of a specific part of the foot or hand, It means the shape of the minimum pattern that is repeated. An example of the spatiotemporal period information will be described with reference to FIG. 4B. In FIG. 4B, a black triangle mark and a white triangle mark are displayed at a spatiotemporal point where the toes intersect on the time axis and the horizontal axis of the image (corresponding to the spatial axis). The spatio-temporal period information is an example of the spatio-temporal period information obtained based on the spatial interval between adjacent black triangle marks and the time interval between adjacent white triangle marks. Further, the shape of the walking pattern (FIG. 4C) itself surrounded by the broken line at the adjacent black triangle position and the broken line at the adjacent white triangle position may be used, or the time length of the step as shown by the curve B11 in FIG. 4B. A frequency characteristic (such as a spectrum intensity in a specific frequency band) obtained by performing frequency analysis with respect to a change or a spatial change in the stride like a curve B12 can be used.
The spatiotemporal cycle information storage unit 130 is a memory or the like that stores the spatiotemporal cycle information extracted by the spatiotemporal cycle information extraction unit 120 together with the detected time, the position in the image, and the like. The spatio-temporal period collating unit 140 is a processing unit that performs collation between the spatio-temporal period information extracted by the spatio-temporal period information extracting unit 120 and the spatio-temporal period information stored in the spatio-temporal period information storage unit 130. .
The spatiotemporal phase information extraction unit 121 is a processing unit that extracts phase information of a spatiotemporal change in walking from the walking sequence extracted by the walking sequence extraction unit 110. “Phase information” means a transition state during a walking motion that is a periodic motion (a position and time at which a predetermined walking posture is taken, or a walking posture at a specific position and time). For example, even in a walking sequence having the same spatiotemporal period, information indicating at which spatiotemporal position the foot is placed on the ground (predetermined walking posture) is spatiotemporal phase information. In addition, the difference in walking posture in two walking sequences compared at the same time or at the same position is also spatiotemporal phase information. Examples of spatiotemporal phase information will be described with reference to FIGS. 5, 6A to 6C, and FIGS. 7A to 7C. FIG. 5 shows the walking trajectory of the foot position as in FIG. 4B, but shows two walking trajectories A010 and A011 having the same spatiotemporal period and different spatiotemporal phases. The walking trajectories A010 and A011 have the same step length and walking cycle, but are different in the position and time at which the feet touch the ground, or the position and time at which both feet intersect. FIG. 6A shows two walking loci (first person walking locus 1802 (broken line) and second person walking locus 1801 (solid line)) detected discontinuously due to the presence of an obstacle 1800 (hatched area). ). Consider a case where phase information is detected from each walking locus. As described above, the phase information is a position and time at which a predetermined walking posture is taken, or a walking posture at a predetermined position and time, and the second person's walking locus 1801 and the first person's walking locus 1802. As for the walking trajectories at different times and positions, phase information is obtained based on the same reference. In this case, the spatio-temporal phase information extraction unit 121 uses the position / time of the predetermined posture (eg, crossing of legs) of the first person's walking information 1802 and the walking posture other than the time and position taken from the periodicity. Is estimated (broken line 1803 in FIG. 6B). Similarly, in FIG. 6C, the spatiotemporal phase information extraction unit 121 estimates the walking posture (broken line 1805) at another time / position from the walking locus 1804 (broken line) on the right side of the obstacle 1800.
Next, the spatio-temporal phase information extraction unit 121 obtains the time and position at which the predetermined walking posture is achieved. Here, a state in which the legs cross each other as a predetermined posture (a state in which the size between the legs is minimized) is considered. FIG. 7A shows the time change or position change between the legs. The distance between the legs can be obtained from the image as the width of the trajectory of both legs in the walking trajectory. Here, the spatio-temporal phase information extraction unit 121, as shown in FIG. 7B, from the first person's leg information 1902 a (broken line) to the leg at the time and position that is not photographed due to the presence of an obstacle 1900 a (shaded area). An intermediate state (posture state) 1903a (broken line) is estimated. Here, the spatio-temporal phase information extraction unit 121 obtains, as phase information, the time or position at which a predetermined posture is initially set on the left side of the image as the first area or the position as the area being imaged. In FIG. 7B, the time or position 1905 is obtained as the phase information for the estimated walking state 1903a of the first person and the time or position 1906 is obtained for the walking state 1901a of the second person. Similarly, in FIG. 7C, phase information 1910 is obtained for the walking state 1909a (broken line) estimated for the walking state 1908a (broken line), and phase information 1911 is obtained for the walking state 1907a (solid line).
Similarly, when the posture at a predetermined time or position is used as the phase information, the spatiotemporal phase information extraction unit 121 similarly obtains the walking state or the estimated walking state at the predetermined time or position. In the case of FIG. 7B, the spatiotemporal phase information extraction unit 121 obtains a leg interval (walking posture) at a predetermined time or position 1904. Here, the phase information for the first person is a value at a predetermined time or position 1904 of the estimated walking state 1903a (broken line), and the phase information for the second person is at a predetermined time or position 1904 of the walking state 1901a (solid line). Value. Similarly, in FIG. 7C, the value at the predetermined time or position 1904 of the estimated walking state 1909a estimated based on the walking state 1908a and the value at the predetermined time or position 1904 of the walking state 1907a are respectively the first person and the second It becomes the phase information of the person.
In the above description, the estimated posture is used only for the first person. However, the estimated posture is also obtained for the second person, and the phase information is obtained from the estimated posture for both the first person and the second person. Good. For example, the position of the obstacle in FIGS. 6A to 6C and FIGS. 7A to 7C and the out-of-range shown in the figure are taken as a common position, and after estimating the estimated state at the common position, the phase information is obtained. Also good.
As the predetermined posture, another state may be used, and a position where the distance between the legs is maximized, a state where the change between the legs is maximized, or the like may be used.
The spatiotemporal phase information storage unit 131 is a memory that stores the spatiotemporal phase information extracted by the spatiotemporal phase information extraction unit 121 together with the detected time, the position in the image, and the like. The spatiotemporal phase collation unit 141 is a processing unit that collates the spatiotemporal phase information extracted by the spatiotemporal phase information extraction unit 121 with the spatiotemporal phase information stored in the spatiotemporal phase information storage unit 131. .
The spatiotemporal position information extraction unit 122 is a processing unit that extracts the spatiotemporal position from which the walking sequence is extracted from the walking sequence extracted by the walking sequence extraction unit 110 and generates the spatiotemporal position information. “Spatio-temporal position information” means the time and place where the walking sequence is detected. An example of the spatiotemporal position information will be described with reference to FIG. In FIG. 5, the time / spatial position at which both feet first cross each other for each of the two walking trajectories is indicated by a dashed cross. In this way, information indicating the position of absolute temporal / spatial walking is spatio-temporal position information.
The spatiotemporal position information storage unit 132 is a memory that stores the spatiotemporal position information generated from the spatiotemporal position information extraction unit 122. The spatiotemporal difference extraction unit 142 is a processing unit that calculates a difference between the spatiotemporal position information generated by the spatiotemporal position information extraction unit 122 and the spatiotemporal position information stored in the spatiotemporal position information storage unit 132. .
The coincidence determination unit 150 is a processing unit that determines coincidence / mismatch between different walking sequences based on the results of the spatiotemporal period collation unit 140, the spatiotemporal phase collation unit 141, and the spatiotemporal difference extraction unit 142. That is, the coincidence determination unit 150 determines whether or not the walking sequence is the same person. An example of a method for determining coincidence / non-coincidence will be described with respect to the spatiotemporal period information as follows. That is, when the number of steps x within a certain time and the number of steps y within a certain distance are used as the spatiotemporal period information, a vector Z1 = (x1, x, y) is a set of x and y obtained from one of the walking sequences to be collated. y1) and the difference between the vector Z2 = (x2, y2) obtained from the other sequence | Z1−Z2 | <θ (θ is a predetermined threshold value), | x1−x2 | <θx, | y1− When both y2 | <θy (θx and θy are predetermined threshold values) are satisfied, the coincidence determination unit 150 determines that the two walking sequences coincide. That is, the coincidence determination unit 150 determines that the walking sequence is the same person.
The coincidence determination unit 150 determines the spatio-temporal phase information and the spatio-temporal position information in the same manner as the spatio-temporal period information. If all items match or the specified number of items match, It can be determined that the two walking sequences match. The determination method is not limited to the above, and a method generally used for pattern recognition or the like can be applied.
For example, when using spatio-temporal phase information, temporal phase information tp1 and spatial phase information (positional phase information) sp1 obtained from the walking sequence of the first person in the moving image, and time when these phase information is obtained or The temporal phase information tp2 obtained from the walking sequence of the second person at a time or position different from the position and the spatial phase information (positional phase information) sp2 are compared. In this case, the coincidence determination unit 150 satisfies either one of | tp1-tp2 | <θt (θt is a predetermined threshold value) and | sp1-sp2 | <θs (θt is a predetermined threshold value). If both are met, or if both are met at the same time, the first person and the second person are determined to be the same. For example, by appropriately setting θt and θs, in the case of FIG. 6B, the coincidence determination unit 150 matches the spatiotemporal phase information of the walking state 1801 and the walking state 1803, and the first person and the first person It is determined that the two people are the same. In the case of FIG. 6C, the coincidence determination unit 150 determines that the walking state 1806 and the walking state 1805 have different spatiotemporal phase information, and the first person and the second person are different. Similarly, the coincidence determination unit 150 determines that the walking state 1901a and the walking state 1903a in FIG. 7B have the same spatio-temporal phase information, and the first person and the second person are the same. In addition, the coincidence determination unit 150 determines that the walking state 1907a and the walking state 1909a in FIG. 7C have different spatiotemporal phase information, and the first person and the second person are different.
The control unit 160 is a processing unit that displays an image sequence used for collation as control based on the result of the match determination by the match determination unit 150. Examples of displays are shown in FIGS. 8A to 8C. FIG. 8A shows an example in which two compared image sequences are displayed on the left and right by enlarging a person's region, and the shooting time and place of each image sequence are displayed together. FIG. 8B shows an example in which the same result as in FIG. 8A is displayed together with the movement locus of the person (arrow in the figure). In these figures, the shooting time and location are displayed in text according to the image sequence. However, for the location, a map is displayed and the shooting position and movement locus are superimposed and displayed. Also good. FIG. 8C shows an example in which, when a plurality of people are included in an image, the matched person's area is highlighted using a broken-line rectangle. In addition to the display, the content of the control by the control unit 160 may be stored in an external storage device (location information storage device) of connection information between walking sequences indicating that different walking sequences match. . In this way, by storing the correspondence relationship between different walking sequences that coincide with each other, it can be used when searching or tracking a walking image of a person.
FIG. 9 shows an example of the storage format of the result of searching and tracking the walking sequence by the above procedure. FIG. 9 shows information on three walking sequences, and includes information on five items for one walking sequence. Each of the five items is a sequence number, spatiotemporal period information, spatiotemporal phase information, spatiotemporal position information, and a matching sequence number. The sequence number is an ID number assigned individually to each walking sequence with different shooting times and shooting cameras. The spatiotemporal period information represents the number of steps x within a certain time and the number of steps y within a certain distance as (x, y). The spatio-temporal phase information indicates the amount of movement to the time / space position where the legs are first crossed after passing the reference time or position, and the time and amount of movement required for one step sequence are 1.0 and 1 respectively. It is expressed as a ratio when. For example, in the case of sequence number 1, it means that the legs cross at a time of 0.5 steps from the reference time, and the legs cross at a distance of 0.1 steps from the reference position.
The spatio-temporal position information indicates the time and place where the walking sequence is first detected. For the location, the pixel coordinate values in the vertical and horizontal directions on the image are shown.
The coincidence sequence number indicates the sequence number of the walking sequence that is determined to match with respect to different walking sequences by searching and tracking. If there is no matching sequence, it may be set to 0, and when there are a plurality of sequences, a plurality of sequences may be written together. By storing the search / tracking result once, when the same search / tracking is performed again, it is possible to omit the matching determination by referring to the information.
Note that the sequence number may be associated with the reference destination (file name, storage address, etc.) of the captured image. The spatial location information in the spatio-temporal position information may be expressed in a dedicated coordinate system as shown in FIG. 9, or may be expressed in a general-purpose coordinate system such as latitude and longitude. .
FIG. 10 is a block diagram showing a configuration of a person search / tracking apparatus 20 to which the person determination apparatus 10 is applied. The person search / tracking apparatus 20 is a specific example of a system or apparatus that implements a method for searching and tracking a person from an image sequence according to the present embodiment, and includes cameras 1010 and 1020, a clock 1030, a storage device 1040, and a processing device 1050. , A display device 1060, an input unit 1070, and a pointing device 1080.
The cameras 1010 and 1020 are an example of the image sequence input unit 100 and take an image including the person 1000. The clock 1030 is a timer for obtaining the shooting time. The storage device 1040 is a hard disk or the like that stores images taken by the cameras 1010 and 1020, shooting times obtained from the clock 1030, human search / tracking results, and the like. The processing device 1050 is a device that performs processing for searching and tracking a person from an image sequence obtained from the cameras 1010 and 1020 or the storage device 1040, and corresponds to the person determination device 10 shown in FIG. The display device 1060 is a display that displays the processing result of the processing device 1050, the input unit 1070 is a keyboard used for search / tracking instructions, and the pointing device 1080 is a mouse or the like used for search / tracking instructions. . FIG. 11 shows an example of pointing. When searching or tracking, as shown in FIG. 11, a person 1091 as an object is designated on the image using a pointer 1090, and the same walking sequence as the person 1091 is searched and tracked.
Each component is connected through a communication path. The communication path may be wired or wireless, and may include a dedicated line and a public line.
Next, the operation of the person determination apparatus 10 in the present embodiment configured as described above will be described with reference to the flowchart of FIG. In this embodiment, a person included in the image sequence 1 is searched for and tracked from the image sequence 2 obtained at different times with a single camera. FIGS. 13A and 13B show examples of the image sequence 1 and the image sequence 2, respectively. FIG. 13A shows an image sequence 1 and shows a sequence in which a person 502 walks in the right direction on the left side of the obstacle 501. On the other hand, FIG. 13B shows an image sequence 2 and shows an image sequence taken at the same place as the image sequence 1 after 10 seconds with the same camera. The image sequence 2 includes an obstacle 501 and a person 503 and a person 504 walking in the right direction.
First, the image sequence input unit 100 inputs the image sequence 1 (step S401). Next, a walking sequence (walking sequence 1) is extracted from the image sequence 1 (step S402). As a walking sequence, a case where a sequence of a lower body region of a person as shown in FIG.
An example in which the walking sequence extraction unit 110 extracts a walking sequence from the image sequence will be described with reference to FIG. First, the walking sequence extraction unit 110 reads one frame image from the image sequence (step S601). The frame image to be read is performed in order of time from among the unread frame images. Next, the walking sequence extraction unit 110 detects a human region from the read frame image (step S602). As a human region detection method, an inter-frame difference method generally used for detecting a moving object or a background difference method in which a background image in which a person is not captured is prepared in advance and a difference from the background image is calculated is used. Even in the case of still images, human template images are prepared in advance, and regions with high similarity are extracted by calculating similarity with the template image (template matching methods such as simple difference calculation and normalized correlation calculation). By doing so, it is possible to detect a human area. Next, the walking sequence extraction unit 110 extracts information representing the walking state from the image of the human region (step S603). The information representing the walking state is information representing the temporal transition of the walking state, such as the locus information of the toe part in FIG. 4B.
Note that the processing in step S602 and step S603 may be performed simultaneously as a series of processing, or the processing result in step S602 may be directly used as the processing result in step S603. Further, the processing may be performed so that the output in step S603 can be obtained directly without explicitly detecting the entire human region as in step S602. For example, in the case of the above-mentioned lower body image, the walking state information may be acquired directly using a template matching method using the lower body image as a template. Finally, the walking sequence extraction unit 110 determines whether or not the currently read frame image is the last frame (step S604). If it is the last frame, the walking sequence extraction process is terminated, and the frame image remains. If yes, the process returns to step S601.
Next, from the walking sequence 1 obtained in step S402, the spatiotemporal period information extracting unit 120, the spatiotemporal phase information extracting unit 121, and the spatiotemporal position information extracting unit 122 are respectively spatiotemporal period information, spatiotemporal phase information, and Spatio-temporal position information is extracted (step S403).
An example of a method for extracting spatiotemporal period information, spatiotemporal phase information, and spatiotemporal position information from the walking sequence shown in FIG. 4B will be described with reference to FIGS. 15 and 16A to 16C.
First, the spatiotemporal period information extraction unit 120 and the like detect the position of the specific walking state from the information of the walking sequence (step S701). The specific walking state will be described with reference to FIGS. 16A to 16C. FIG. 16A shows the result of detecting the specific walking state position for the walking sequence of FIG. 4B. The two black corrugated bands that cross each other in FIG. 16A represent the temporal movement trajectory of the toes. Here, the horizontal axis represents the position in the horizontal direction of the image, and the vertical axis represents time. Here, two crossing positions, that is, positions where both feet cross (broken line positions in the figure) are defined as specific walking state positions. Here, the position of the intersection can be detected by preparing a shape pattern of the intersection as shown in FIG. 16B in advance and performing template matching or correlation calculation. FIG. 16C shows an example of the detection process. In FIG. 16C, the degree of coincidence of the shape is calculated while shifting the position of the detection template 801 with respect to the walking locus 800. If the degree of matching by matching is greater than or equal to a predetermined value, it is determined that the user is in a specific walking state. In this way, the intersection position of the broken line in FIG. 16A is obtained.
It should be noted that the specific walking state is not limited to when the legs cross, but may be a state where the legs are most widened. The state where the legs are most widened corresponds to the position of the position where the interval between the intersecting bands is the widest on the walking locus of FIG. Step S701 is performed until all the specific walking states are detected, and then the process proceeds to step S703 (step S702).
Next, the spatiotemporal period information extraction unit 120 generates spatiotemporal period information by calculating the interval between the detected specific walking state positions (step S703). The period information may be separately calculated without obtaining the position of the specific walking state using Fourier analysis, wavelet analysis, or autocorrelation method. In this case, a Fourier transform, a wavelet transform, or an autocorrelation method may be applied to the temporal change in the position of the corrugated band in FIG. 16A and the spatiotemporal change in the width of the two bands. Further, as the spatiotemporal period information, the shape of the minimum unit of the periodic walking locus in FIG. 16A itself may be used as a pattern. In this case, the pattern has one wave shape of two bands in the range surrounded by vertical and horizontal broken lines in FIG. 16A.
Next, the spatiotemporal phase information extraction unit 121 calculates spatiotemporal phase information (step S704). The spatio-temporal phase information represents a spatio-temporal movement amount from the time / space position to the time / space position where both feet are first crossed (a specific walking state appears) after passing the reference time or space position. In the case of using the time or position at which a predetermined posture is used as the spatiotemporal phase information, in the example of FIG. 7B, the time or position at which the space between the legs is minimized is obtained, and 1905 obtained from the estimated walking state 1903a for the walking of 1902a. The value of 1906 becomes temporal phase information or spatial phase information, and the value of 1906 becomes temporal phase information or spatial phase information for a 1901a walk. When the posture at a predetermined time or position is used as the spatiotemporal phase information, the value at 1904 of the estimated walking state 1903a (the value between the legs) becomes the temporal phase information or the spatial phase information for the walking of 1902a, and 1901a The value at 1904 is time phase information or spatial phase information for walking.
In the example of FIG. 5, when the time axis reference is the upper end of the walking trajectory diagram, the time from the upper end to the first position where both feet are first crossed (the crossing position of the broken line) is time phase information, Assuming that the position reference is the vertical line A013 of the walking trajectory map, the distance between the vertical line A013 and the position where the two legs are closest to the vertical line A013 on the right side of the vertical line A013 is the spatial phase information. The method of expressing the movement amount is not limited to the above, and the movement amount may be expressed by a relative size based on the time taken for the sequence for one step and the movement amount.
Note that spatiotemporal phase information means phase information in which the specific walking state appears in the image, and even if the walking sequence has the same spatiotemporal cycle, the feet are spatiotemporally placed on the ground or the legs are crossed. Walking with different spatio-temporal timings in the states such as has different values. In FIG. 5, the spatio-temporal period of walking is the same in the walking sequences A011 and A012, but the spatiotemporal phase information defined as described above has different values.
Next, the spatiotemporal position information extraction unit 122 calculates spatiotemporal position information (step S705). The spatiotemporal position information is the time when the first specific walking state is detected and the position on the image. The spatiotemporal position information is information representing absolute position coordinates in the spatiotemporal position of the walking detection position, and the detection position of the second step or the last detection position may be used.
By detecting the specific walking state, not only the spatiotemporal period of walking but also spatiotemporal phase information and spatiotemporal position information of walking can be obtained.
Next, the spatiotemporal period information, the spatiotemporal phase information, and the spatiotemporal position information obtained in step S403 are respectively the spatiotemporal period information storage unit 130, the spatiotemporal phase information storage unit 131, and the spatiotemporal position information storage unit 132. (Step S404).
Next, the image sequence input unit 100 acquires the image sequence 2 for searching for people in the same manner as in step S401 (step S405). Then, the walking sequence extraction unit 110 extracts the walking sequence 2 from the image sequence 2 (step S406). Subsequently, the walking sequence extraction unit 110 determines whether there is another walking sequence as a result of the processing in step S406 (step S407). If there is no other walking sequence (No in step S407), the process ends. If it exists (Yes in step S407), the spatiotemporal period information extraction unit 120, the spatiotemporal phase information extraction unit 121, and the spatiotemporal position information extraction unit 122 will start from the walking sequence 2 as in the case of the walking sequence 1. Spatial period information, spatiotemporal phase information, and spatiotemporal position information are extracted (step S408).
Next, the spatiotemporal period verification unit 140, the spatiotemporal phase verification unit 141, and the spatiotemporal difference extraction unit 142 respectively store the spatiotemporal period information, spatiotemporal phase information, and spatiotemporal position of the walking sequence 1 stored in step S404. The information is collated with the spatiotemporal period information, spatiotemporal phase information, and spatiotemporal position information extracted in step S408 (step S409). In the collation, all three pieces of information may be used, or the collation can be performed using only one of the spatiotemporal period information or the spatiotemporal phase information.
As a collation method, a criterion for the degree of coincidence may be set in advance for each of the spatiotemporal period information, the spatiotemporal phase information, and the spatiotemporal position information, and it may be determined that all three pieces of information satisfy the criterion. For example, in the case of comparing sequences having different representations as shown in FIG. 9, if each spatiotemporal period information is (x 1, y 1), (x 3, y 3), the individual determination methods are | x 1 −x 3 | = Dx < When both θx and | y1−y3 | = Dy <θy are satisfied, it is determined that the two match. Here, θx and θy are predetermined threshold values. Similarly, when the respective spatial phase information is set as (w1, z1), (w3, z3), if both satisfy | w1−w3 | = Dw <θw and | z1−z3 | = Dz <θz judge. Here, θw and θz are predetermined threshold values. Similarly, when the spatiotemporal position information is t1, (xx1, yy1) and t3, (xx3, yy3), | t1−t3 | = Dt <θt, (xx1−xx3) * (xx1−xx3) + When (y1−yy3) * (yy1−yy3) = Dxy <θd is satisfied, it is determined that the two match. Here, θt and θd are predetermined threshold values.
Further, the above three pieces of information may be associated with each other to make a match determination. For example, the product or sum of the spatio-temporal period information differences Dx, Dy and the spatio-temporal phase information differences Dw, Dz and the spatio-temporal position information differences Dt, Dxy may be compared with a predetermined matching criterion. . For example, (Dx + Dy + Dw
+ Dz + Dt + Dxy) <θsum or (Dx × Dy × Dw × Dz × Dt × Dxy) <θmul
Are determined to match. Here, θmul is a predetermined threshold value. Further, based on the magnitude of the difference between the spatiotemporal position information, the reference for the difference between the spatiotemporal period information and the difference between the spatiotemporal phase information may be changed. The spatio-temporal period value and spatio-temporal phase value can change as the time and space increase, so if the difference in spatio-temporal position information increases, the standard for the difference in spatio-temporal period information and spatio-temporal phase information difference By loosening, it becomes possible to reduce detection omissions. For example, when the differences Dt and Dxy in the spatio-temporal position information satisfy Dt> θt or Dxy> θxy, the determination threshold values θx, θy, θw, and θz are multiplied by α (α is 1.0 or more). To determine the match.
When spatio-temporal periodic information is used, the value of spatio-temporal periodic information is not easily changed even if the orientation of the person with respect to the camera changes, so that it is easy to search and track between temporally separated image sequences. .
Moreover, when spatio-temporal phase information is used, there exists an effect that it is easy to distinguish from the walking sequence of others who walk in the same spatio-temporal cycle.
Subsequently, the coincidence determination unit 150 determines whether or not the walking sequence 1 and the walking sequence 2 match based on the collation result in step S409 (step S410). If they do not match (No in step S411), the process returns to step S406, and a new walking sequence is acquired (step S406). If they match (Yes in step S411), the control unit 160 displays the image sequence 1 and the image sequence 2 on the display device 1060, and highlights the human region of the matching walking sequence. An example of display by the control unit 160 is shown in FIG. In FIG. 17, an image sequence 1 is displayed in an area 1130, an image sequence 2 is displayed in an area 1140, and a circumscribed rectangle 1110, 1120 is added to the human area corresponding to the matched walking sequence for cooperative display.
In general, spatio-temporal periodic information (walking pattern) is based on personality (such as walking habits), personal situation (such as hurrying or walking slowly), and the type of footwear (heel height or ankle Because it changes under the influence of various factors such as the range of movement), belongings (whether a heavy object is held on one side), clothes (such as the range of movement of the legs), road surface conditions (slipperiness, inclination, etc.) It is difficult to identify an individual. Here, by calculating the spatio-temporal position difference between two walking sequences to be collated using spatio-temporal position information, and changing the reference for coincidence according to the spatio-temporal position difference, places, footwear, clothes, belongings, etc. The degree of change in space and time can be reflected, and it is possible to prevent erroneous matching. For example, as shown in FIG. 13A and FIG. 13B, if the time-space difference is about 10 seconds, a walking sequence having a small difference in spatio-temporal period information and a difference in spatio-temporal phase information may be searched and tracked. For example, in the case of Dt <10 seconds, the above determination threshold values θx, θy, θw, θz are multiplied by β (β is a constant less than 1.0) to make a coincidence determination. By using the method as described above, for the person 502 in the image sequence of FIG. 13A, appropriately selecting the person 503 whose walking sequence information matches among the two persons in the image sequence of FIG. 13B, etc. Is possible.
As described above, according to the present embodiment, spatiotemporal period information obtained from a walking sequence, spatiotemporal phase information, and spatiotemporal position information are detected, and a walking sequence match determination is performed based on these information. By performing the above, it becomes possible to search and track people included in image sequences at different times while suppressing the influence of the size and orientation of the people in the image.
In this embodiment, the walking sequence is collated using both the spatiotemporal period information and the spatiotemporal phase information. However, the walking sequence is collated only by either the spatiotemporal period information or the spatiotemporal phase information. Is possible, and the effects of the present invention can be obtained. By combining the two, detailed collation is possible, and the accuracy of search / tracking can be improved.
In addition, the image sequence input to the image sequence input unit 100 is preferably a time length or the number of frames including at least one step of walking, and a higher number of steps than one step is expected to improve collation accuracy. it can. The length of time including the walking process of one or more steps is preferably an image sequence of about 0.5 seconds or more (about 15 frames or more at 30 frames / second), and a specific walking state is detected at least twice or more. It is desirable to be able to do it.
Note that although an example in which the image sequence is obtained directly from the camera has been described in Embodiment 1, the same effect can be obtained by reading and using the image sequence recorded in the storage device 1040 or the like.
Next, Embodiment 2 of the present invention will be described with reference to FIGS. 18A, 18B, and 19. FIG.
The basic configuration of the second embodiment is the same as that of the first embodiment, but image sequences obtained from two different cameras are handled as an image sequence 1 and an image sequence 2, respectively, and a person is searched and tracked. Is. Examples of images are shown in FIGS. 18A and 18B. 18A shows the image sequence 1 and FIG. 18B shows the image sequence 2. 18A and 18B, a rectangular parallelepiped obstacle 900 is displayed. In the image sequence 1 shown in FIG. 18A, the person 922 is hidden by the obstacle 900, and only the person 912 is shown. On the other hand, in the image sequence 2 shown in FIG. 18B, a person 921 and a person 922 are shown. The person 912 corresponds to the person 922, but the two persons in the image sequence 2 are walking close to each other and have the same appearance and clothes, and whether the person corresponding to the person 912 is the person 921 or the person 922 is a color. And textures and motion vectors are indistinguishable. Here, the grid-like broken lines in FIGS. 18A and 18B are displayed by superimposing the position coordinates on the ground, and are displayed for explaining the correspondence between the position information of the two image sequences. The dashed grid can be obtained in advance by measuring the correspondence (time-space correction information) between the position in the camera image and the position of the shooting location, or by performing geometric calculation based on the specifications of the camera arrangement and the optical system. The grid in FIG. 18A and the grid in FIG. 18B represent corresponding positions. Since coordinate conversion between corresponding points on different planes in the image can be expressed by a 3 × 3 plane projection matrix H, the matrix H may be calculated and held. K. Kanatani, N. Ohta and Y. Kanazawa, "Optimal homography computation with a reliability measure," IEICE Transactions on Information and Systems, Vol. E83-D, No.7, pp.1369- Existing methods such as 1374 (July 2000) can be used.
FIG. 19 is a functional block diagram showing the configuration of the person determination device 15 in the present embodiment. This person determination device 15 further includes a spatiotemporal correction unit 170 in addition to the configuration included in the person determination device 10 according to the first embodiment. The spatiotemporal correction unit 170 performs correction using the spatiotemporal correction information when extracting the walking sequence or calculating the spatiotemporal periodic information, spatiotemporal phase information, and spatiotemporal position information, so that the spatiotemporal correction in different image sequences is performed. A processing unit that compensates for inconsistencies. Here, the spatiotemporal correction unit 170 is an example of a correction unit that performs a spatiotemporal correction process in the extraction of walking information.
The person determination device 15 can process a video from a different camera in the same procedure as in the first embodiment, and can specify a person in the image sequence 2 corresponding to a person in the image sequence 1. Since the arrangement in the target image is different due to the difference in the arrangement of the cameras, the grid lines are held as spatio-temporal correction information for each camera (or for each image sequence), and the space for extracting the walking sequence It is used as correction information for general position coordinates. In other words, the spatiotemporal correction unit 170 stores, as correction information, information that specifies grid lines that two-dimensionally divide the walking surface at the shooting location at a fixed distance.
Then, the spatiotemporal correction unit 170 performs correction processing using the spatiotemporal correction information, so that spatiotemporal periodic information, spatiotemporal phase information, and spatiotemporal position information can be collated between images of different cameras. It becomes possible. For example, the spatiotemporal correction unit 170 corrects spatiotemporal periodic information, spatiotemporal phase information, and spatiotemporal position information in a spatiotemporal manner according to the ratio of each side or area of the small region surrounded by the grid lines. (Multiply by proportionality factor). At this time, as the spatiotemporal phase information, a spatiotemporal position where a specific walking state is first obtained after a specific lattice line is exceeded may be used. With such a configuration, it is possible to associate a person (not shown) hidden in the obstacle 900 with the person 921, and associate the person 912 with the person 922.
Further, in the above example, when the walking sequence is extracted, the correspondence relationship of the positions is used. You may perform the process of. Even when image conversion is performed, the above-described plane projection matrix H is used to apply the matrix H to the pixel position on the walking plane (ground), so that the plane (ground ) Can be converted to the upper position. For this reason, it is possible to convert an image by performing the same conversion for all the pixels. When calculating spatio-temporal period information, spatio-temporal phase information, and spatio-temporal position information, it is possible to collate walking sequences without the influence of camera placement by performing correction using positional relationships. .
Also, when the frame rate is different between two image sequences, the spatio-temporal correction unit 170 performs frame rate conversion on one side so that the frame rates are matched in advance, or the frame rate is converted when a walking sequence is extracted. Alternatively, by correcting the temporal information when calculating the spatiotemporal period information, spatiotemporal phase information, and spatiotemporal position information, it becomes possible to search and track people between image sequences of different frame rates. For example, if the frame rates of the two image sequences to be compared are 15 frames / second and 30 frames / second, respectively, a frame sequence of 15 frames / second is generated by thinning out frames from the latter image sequence every other frame. After that, walking sequences between image sequences are detected and verified.
In this case, the information spatiotemporal correction information of the frame rate necessary for correction may be stored in advance in a storage device or the like in a state associated with the image sequence.
In general, different cameras often change the appearance of people on the image due to differences in target orientation, lighting conditions, and camera characteristics. Therefore, the continuity of colors and motion vectors and the image pattern of human areas are often different. It is difficult to search and track the same person appropriately with the tracking method using itself. However, by using the method in this embodiment, even if the person has a different orientation, color, and appearance, different image sequences can be obtained by using spatiotemporal period information and spatiotemporal phase information obtained from the walking sequence of the same person. It becomes possible to search and track people inside. In particular, when the fields of view of different cameras include the same place and the same person can be photographed from different directions, it is possible to more effectively associate human sequences by using time phase information.
In the above example, the positions of the camera images are associated with each other in advance. However, when the time period or the phase is mainly used, even when the association is not performed, the walking sequences are collated, and the present invention is performed. It is possible to obtain the effect.
Part or all of the processing in the above embodiment may be performed by a dedicated device, or may be performed by a communication device such as a terminal or a base station, or a CPU built in the computer executing a processing program. It may be broken.
The present invention is installed in, for example, a street as a person determination apparatus that determines whether persons included in different image sequences are the same person, a person search tracking apparatus that searches for and tracks a person from an image sequence, and the like. It can be used as a monitoring system.
FIG. 1A is a diagram illustrating an example of a detection rectangle in a conventional person search and tracking device. FIG. 1B is a diagram illustrating an example of a detection rectangle in a conventional person search and tracking device. FIG. 1C is a diagram illustrating movement of a detection rectangle in a conventional person search and tracking device. FIG. 2 is a functional block diagram showing the configuration of the person determination device according to Embodiment 1 of the present invention. FIG. 3 is a diagram showing an example of an image sequence according to Embodiment 1 of the present invention. FIG. 4A is a diagram illustrating an example of a sequence of human lower body images. FIG. 4B is a diagram showing an example of a walking sequence according to Embodiment 1 of the present invention. FIG. 4C is a diagram illustrating an example of the shape of the minimum pattern of the walking sequence. It is a figure which shows the spatiotemporal phase information and spatiotemporal position information in Embodiment 1 of this invention. FIG. 6A is a diagram showing an example of a walking locus in the first embodiment of the present invention. FIG. 6B is a diagram showing an example of an estimated walking state in the first embodiment of the present invention. FIG. 6C is a diagram showing an example of walking states with different phase states in Embodiment 1 of the present invention. FIG. 7A is a diagram showing an example of a relationship between a walking locus and a change between legs in Embodiment 1 of the present invention. FIG. 7B is a diagram showing an example of a change between legs in the first embodiment of the present invention. FIG. 7C is a diagram showing an example of a change between legs in the first embodiment of the present invention. FIG. 8A is a diagram showing an example of a display of a walking sequence according to Embodiment 1 of the present invention. FIG. 8B is a diagram showing an example of a display of a walking sequence according to Embodiment 1 of the present invention. FIG. 8C is a diagram showing an example of a display of a walking sequence according to Embodiment 1 of the present invention. FIG. 9 is a diagram illustrating an example of a storage format of a result of searching and tracking a walking sequence according to Embodiment 1 of the present invention. FIG. 10 is a block diagram showing the configuration of the person search / tracking apparatus according to Embodiment 1 of the present invention. FIG. 11 is a diagram showing an example of a screen for instructing search / tracking in Embodiment 1 of the present invention. FIG. 12 is a flowchart showing an example of the collation procedure in the first embodiment of the present invention. FIG. 13A is a diagram showing an example of an image sequence 1 according to Embodiment 1 of the present invention. FIG. 13B is a diagram showing an example of an image sequence 2 according to Embodiment 1 of the present invention. FIG. 14 is a flowchart showing an example of a walking sequence extraction procedure according to Embodiment 1 of the present invention. FIG. 15 is a flowchart showing an example of a procedure for extracting spatiotemporal period information, spatiotemporal phase information, and spatiotemporal position information according to Embodiment 1 of the present invention. FIG. 16A is a diagram showing an example of detection of a specific walking state in the first embodiment of the present invention. FIG. 16B is a diagram showing an example of a detection template for a specific walking state according to Embodiment 1 of the present invention. FIG. 16C is a diagram showing an example of a specific walking state detection process in the first embodiment of the present invention. It is a figure which shows an example of the display by the control part in Embodiment 1 of this invention. FIG. 18A is a diagram showing an example of an image sequence 1 according to Embodiment 2 of the present invention. FIG. 18B is a diagram showing an example of an image sequence 2 according to Embodiment 2 of the present invention. FIG. 19 is a functional block diagram showing the configuration of the person determination device according to Embodiment 2 of the present invention.
DESCRIPTION OF SYMBOLS 10, 15 Person determination apparatus 20 Person search tracking apparatus 100 Image sequence input part 110 Walking sequence extraction part 120 Spatio-temporal period information extraction part 121 Spatio-temporal phase information extraction part 122 Spatio-temporal position information extraction part 130 Spatio-temporal period information storage part 131 Spatio-temporal phase information storage unit 132 Spatio-temporal position information storage unit 140 Spatio-temporal period verification unit 141 Spatio-temporal phase verification unit 142 Spatio-temporal difference extraction unit 150 Match determination unit 160 Control unit 170 Spatio-temporal correction unit 180 Walking state estimation unit 190 Determination Unit 200 Walking posture detection unit 1010, 1020 Camera (image sequence input unit)
1030 Clock 1040 Storage device 1050 Processing device 1060 Display device 1070 Input device 1080 Pointing device
A person determination device for determining whether or not persons included in different image sequences are the same,
An image sequence input means for receiving an input of a first image sequence and a second image sequence acquired at a different time or a different image sensor from the first image sequence;
Walking sequence extraction means for extracting first and second walking sequences, which are image sequences indicating the walking state of the person, from the input first and second image sequences, respectively;
From the extracted first and second walking sequences, in the first and second spatio-temporal period information, which is information indicating the temporal or spatial walking period of the person, and the periodic walking movement of the person, respectively. Walking that extracts first and second spatiotemporal phase information, which is temporal or spatial phase information, as first and second walking information, which is information that identifies periodic movements of a person's walking Information extraction means;
Based on the first and second spatio-temporal phase information included in the extracted first and second walking information, the persons included in the first and second image sequences have a predetermined walking posture. Walking information matching means for matching walking information by comparing time or position;
Determination means for determining whether or not the persons included in the first and second image sequences are the same based on the collation result by the walking information collating means,
The walking information collating means
Based on the first spatiotemporal phase information included in the first walking information, the spatiotemporal phase information at a time or position different from the first image sequence of the person included in the first image sequence is estimated. A phase information estimation unit to
Based on the spatiotemporal phase information and the second spatiotemporal phase information estimated by the phase information estimation means, a time or position at which a person included in the first and second image sequences assumes a predetermined walking posture And a walking information matching unit that compares walking information by comparing the walking information.
Based on the first and second spatio-temporal phase information included in the extracted first and second walking information, respectively, the person included in the first and second image sequences at the same time or position Walking information matching means for comparing walking information by comparing walking posture;
Based on spatiotemporal phase information included in the first spatiotemporal walking information, spatiotemporal phase information of a person included in the first image sequence at a time or position different from that of the first image sequence is estimated. A phase information estimator;
Based on the spatiotemporal phase information and the second spatiotemporal phase information estimated by the phase information estimation means, the walking posture of the person included in the first and second image sequences at the same time or position is determined. The person determination apparatus according to claim 1 , further comprising: a walking information matching unit that compares walking information by comparing.
Walking information collating means for collating the extracted first and second walking information;
A determination unit that determines whether or not the persons included in the first and second image sequences are the same based on a verification result by the walking information verification unit;
Correction information storage means for preliminarily storing correction information indicating the correspondence between the position on the image and the position at the shooting location in each of the first and second image sequences;
Correction means for performing spatiotemporal correction processing in the extraction of the first and second walking information by the walking information extraction means based on the correction information stored in the correction information storage means. Person determination device.
The person determination apparatus according to claim 3 , wherein the correction information storage unit stores, as the correction information, information for specifying a grid line that two-dimensionally divides the walking surface at the shooting location at a constant distance. .
Walking sequence detection means for detecting first and second walking sequences that are image sequences indicating the walking states of the first and second persons included in the image sequence;
A walking posture transition estimating means for estimating information indicating a transition of a walking posture in a periodic walking motion of the first person at a time or position different from the walking sequence of the first person;
The consistency between the estimated information indicating the transition of the walking posture of the first person and the information indicating the transition of the walking posture of the second person is determined. A person determination apparatus comprising: a determination unit that determines that a person and the second person are the same.
A person search and tracking device for searching or tracking a specific person in an image sequence in which a person is captured,
A person determination device comprising: determination means for determining whether or not the persons included in the first and second image sequences are the same based on a collation result by the walking information collation means;
The first and second walking sequences corresponding to the first and second walking information when the first and second walking information are matched by the walking information matching means included in the person determination device. A person search and tracking device comprising: walking sequence storage means for storing and associating each other.
Display means for displaying the first and second image sequences received by the image sequence input means provided in the person determination device;
The display means performs highlighting so as to distinguish a person determined to be the same by the determination means included in the person determination apparatus from other persons included in the first and second image sequences. A person search and tracking device characterized by the above.
JP2006531421A 2004-08-03 2005-07-27 Person determination device and person search tracking device Active JP3910629B2 (en)
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JP2006531421A Active JP3910629B2 (en) 2004-08-03 2005-07-27 Person determination device and person search tracking device
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