Patent Document

CROSS-REFERENCE TO RELATED APPLICATIONS 
   This application is a continuation of U.S. application Ser. No. 10/817,840, filed Apr. 6, 2004, which is a continuation of U.S. application Ser. No. 09/772,887 filed Jan. 31, 2001, now U.S. Pat. No. 6,744,908, and further is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2000-054948, filed Feb. 29, 2000, the entire contents of each of which are incorporated herein by reference. 

   BACKGROUND OF THE INVENTION 
   The present invention relates to a traffic density analysis apparatus for analyzing the traffic density from a video image. 
   To detect vehicles from a video image and analyze the traffic density, generally, a change in pixel values in a video screen must be checked. However, such processing related to pixel values requires a large calculation amount. For example, for CIF format often used in ITU-T H.261, H.263, ISO/IEC MPEG-4 or the like, processing must be performed for 352×288 pixels, i.e., a total of 101,376 pixels. For such processing with a large calculation amount, dedicated hardware must be prepared, resulting in a serious problem of cost. 
   As described above, the prior art requires a very large calculation amount to analyze the traffic density by detecting vehicles from a video image. 
   BRIEF SUMMARY OF THE INVENTION 
   It is an object of the present invention to provide a traffic density analysis apparatus based on an encoded video, which can perform high-speed stable analysis. 
   According to the present invention, there is provided a traffic density analysis apparatus based on an encoded video, which stably executes analysis at a high speed with a small calculation amount by narrowing down a region to undergo traffic density analysis processing using a video encoding/decoding technique. 
   According to the present invention, there is provided a traffic density analysis apparatus comprising a video decoder section which decodes video encoded data obtained by encoding a video signal corresponding to an analysis region and outputs a decoded video signal, and an analyzer section which sets a specific region in a screen for the decoded video signal output from the video decoder section and analyzes a traffic density in the analysis region from information related to a moving object which passes through the specific region. 
   In the analyzer section, for example, it is determined, whether each of predetermined blocks is a moving object, from information contained in the video encoded data and pieces of information of current and previous frames of the decoded video signal. Image analysis is performed for the decoded video signal in a block determined as a moving object, thereby acquiring object information related to setting of the specific region and the moving object. 
   More specifically, in the analyzer section, for example, the traffic density is estimated using the average velocity and number of moving objects which pass through the specific region as the information related to the moving object which passes through the specific region. 
   According to the present invention, there is also provided a traffic density analysis apparatus comprising a video encoder section which encodes a video signal corresponding to an analysis region and outputs video encoded data, and an analyzer section which sets a specific region in a screen for a local decoded signal generated by the video encoder section and analyzes a traffic density in the analysis region from information related to a moving object which passes through the specific region. 
   The analyzer section determines whether each of predetermined blocks is a moving object from information contained in the video encoded data and pieces of information of current and previous frames of the local decoded signal, and performs image analysis for the local decoded signal in a block determined as a moving object, thereby acquiring object information related to setting of the specific region and the moving object. 
   In this analyzer section as well, for example, the traffic density is estimated using the average velocity and the number of moving objects which pass through the specific region as the information related to the moving object which passes through the specific region. 
   As described above, in the traffic density analysis apparatus of the present invention, the traffic density can be stably analyzed at a high speed with a small calculation amount by narrowing down a region to undergo actual traffic density analysis processing to a specific region using information generated by the video decoding apparatus or video encoding apparatus. 

   
     BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING 
       FIG. 1  is a view showing the arrangement of a traffic density monitoring system using a traffic density analysis apparatus according to the first embodiment of the present invention; 
       FIG. 2  is a block diagram showing the arrangement of a monitor camera of the first embodiment; 
       FIG. 3  is a block diagram showing the arrangement of a monitoring center of the first embodiment; 
       FIG. 4  is a block diagram showing the arrangement of a video decoder/analyzer section of the first embodiment; 
       FIG. 5  is a view showing an example of estimation of a specific vehicle in the first embodiment; 
       FIG. 6  is a view showing the estimation range in estimating the traffic density in the first embodiment; 
       FIG. 7  is a block diagram showing the arrangement of a terminal section of the first embodiment; and 
       FIG. 8  is a block diagram showing the arrangement of a video encoding/analyzing apparatus according to the second embodiment of the present invention. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   The embodiments of the present invention will be described below with reference to the accompanying drawing. 
   (First Embodiment) 
     FIG. 1  shows the overall arrangement of a traffic density monitoring system according to the first embodiment of the present invention. This traffic density monitoring system comprises monitor camera sections  1 , a monitoring center  2 , and a terminal section  3 . 
   Each monitor camera section  1  is installed in a monitor region (road whose traffic density should be monitored) to encode a video image obtained by sensing the monitor region and transmit the video encoded data to the monitoring center  2  through a cable or radio public channel or a radio channel. The monitoring center  2  decodes and analyzes video encoded data of images sensed by the monitor camera sections  1  in the respective regions, generates necessary traffic information in consideration of position information and request information from the terminal sections  3 , and transmits the traffic information to the terminal sections  3 . Each terminal section  3  is installed in a car that travels on the road to transmit position information or request information to the monitoring center  2  and receive necessary traffic information and video information. 
     FIG. 2  shows the arrangement of the monitor camera section  1  of this embodiment. A video signal output from a video camera  11  is compress-encoded by a video encoder section  12 , and the thus obtained video encoded data is transmitted to the monitoring center  2  through a cable or radio public channel or a dedicated line. 
     FIG. 3  shows the arrangement of the monitoring center  2  of this embodiment. Video encoded data transmitted from the plurality of (n) monitor camera sections  1  through a cable or radio dedicated line or public channel are received by receiver sections  21 - 1  to  21 - n , respectively, and sent to video decoder/analyzer sections  22 - 1  to  22 - n  and multiplexer section  27 . 
   The video decoder/analyzer sections  22 - 1  to  22 - n  (to be described later in detail) decode video encoded data, display video images obtained by decoding, i.e., images obtained by the monitor camera sections  1  on display sections  23 - 1  to  23 - n , respectively, and simultaneously analyze the traffic density. The analysis results from the video decoder/analyzer sections  22 - 1  to  22 - n  are collected by a situation analyzing section  24 . 
   Position information or request information of each car from the terminal section  3  is received by a transceiver section  28  and input to the situation analyzing section  24 . The situation analyzing section  24  systematically analyzes the analysis results obtained by analyzing the images from the monitor camera sections  1  by the video decoder/analyzer sections  22 - 1  to  22 - n  and the position information and request information from the terminal sections  3 . A video selector section  25  selects a necessary image from the analysis result from the situation analyzing section  24 . An additional information generator section  26  generates message or voice information, as needed, on the basis of the operation of an operator who checks the analysis result from the situation analyzing section  24  or the displays on the display sections  23 - 1  to  23 - n  which are displaying the images from the monitor camera sections  1 , and sends the information to the multiplexer section  27 . 
     FIG. 4  shows the arrangement of a video decoding/analyzing apparatus using a video decoding processing apparatus based on the present invention as the arrangement of each of the video decoder/analyzer sections  22 - 1  to  22 - n  of the first embodiment. This video decoding/analyzing apparatus is formed from two sections: a video decoder section  100  and a traffic density analyzer section  200 . 
   In the video decoder section  100 , video encoded data input through a transmission channel or storage medium is temporarily stored in an input buffer  101 . The video encoded data read out from the input buffer  101  is demultiplexed by a demultiplexer section  102  on the basis of syntax in units of frames and output to a variable-length decoder section  103 . The variable-length decoder section  103  decodes the variable-length code of information of each syntax and outputs decoded information, and mode information and motion vector information of each macro block. 
   In the variable-length decoder section  103 , if the mode of a macro block is INTRA, a mode change-over switch  109  is turned off. Hence, quantized DCT coefficient information decoded by the variable-length decoder section  103  is inverse-quantized by a dequantizer section  104  and then subjected to inverse discrete cosine transformation by an IDCT section  105 . As a result, a reconstructed video signal is generated. This reconstructed video signal is stored in a frame memory  107  as a reference video signal through an adder  106  and also output as a decoded video signal  112 . 
   In the variable-length decoder section  103 , if the mode of a macro block is INTER and NOT — CODED, the mode change-over switch  109  is turned on. Hence, the quantized DCT coefficient information decoded by the variable-length decoder section  103  is inverse-quantized by the dequantizer section  104  and then subjected to inverse discrete cosine transformation processing by the IDCT section  105 . The output signal from the IDCT section  105  is added, by the adder  106 , to the reference video signal which is motion-compensated by a motion compensation section  108  on the basis of the motion vector information decoded by the variable-length decoder section  103 , thereby generating a decoded video signal  112 . This decoded video signal  112  is stored in the frame memory  107  as a reference video signal and also extracted as a final output. 
   On the other hand, in the traffic density analyzer section  200 , a moving object determination section  201  for determining a moving object in units of macro blocks determines whether a macro block is a moving object on the basis of encoding information output from the variable-length decoder section  103 , the decoded video signal of the current frame output from the adder  106 , and the decoded video signal (reference video signal) of the previous frame output from the frame memory  107 . The encoding information is information contained in video encoded data and variable-length-decoded by the variable-length decoder section  103 . More specifically, encoding information is mode information or motion vector information. 
   For example, if the mode of a macro block of interest is INTRA or INTER — CODED on the basis of mode information, the moving object determination section  201  temporarily determines that the macro block is highly probably a moving object, and determines a moving object by comparing the decoded video signal of the current frame with that of the previous frame only for this macro block. Alternatively, the moving object determination section  201  may temporarily determine on the basis of, e.g., motion vector information that a macro block where large motion vectors concentrate is highly probably a moving object, and determine a moving object by comparing the decoded video signal of the current frame with that of the previous frame only for the macro block. 
   The determination result from the moving object determination section  201  is sent to a macro-block analyzer section  202 , where image analysis of the macro block determined as a moving object is done. The image analysis result for this macro block is sent to a specific vehicle estimator section  203  and traffic density estimator section  204 . 
   The specific vehicle estimator section  203  estimates a specific vehicle from a color and shape in the image analysis result for the macro block and outputs an estimation result  211 .  FIG. 5  shows an example in which a specific vehicle is estimated from specific color and shape. To determine the color of a vehicle, first, color correction is performed in accordance with the environment to set a color space. The color of vehicle is determined in this color space. The shape of vehicle is determined by pattern matching. The velocity of vehicle is measured by marking a specific vehicle determined in this way. 
   The traffic density estimator section  204  sets a specific region on the screen from the image analysis result for the macro block, estimates the traffic density from the average velocity and number of moving objects that pass through the specific region, and outputs an estimation result  212 .  FIG. 6  shows an example in which measurement regions  1  and  2  are set in units of lanes as specific regions (this example shows two lanes), and the traffic density is estimated by calculation on the basis of the average velocity and number of moving objects that pass through measurement regions  1  and  2 . 
     FIG. 7  shows the arrangement of the terminal section  3  of this embodiment. A receiver section  31  receives information sent from the monitoring center  2 . A demultiplexer section  32  demultiplexes video encoded information and additional information. The video encoded information is decoded by a video decoder section  33 , so a decoded image and additional information are displayed on a display section  34 . On the other hand, request information for an information request section  35  serving as an information input section for inputting information requested by the user and position information from a position detection section  36  for detecting the position of the terminal are transmitted to the monitoring center  2  through a transmission section  37 . 
   (Second Embodiment) 
     FIG. 8  is a block diagram of a video encoding/analyzing apparatus which combines a video traffic density analysis apparatus according to the second embodiment of the present invention with a video encoding apparatus. 
   Referring to  FIG. 8 , an input video signal  321  is segmented into a plurality of macro blocks (each block has 16×16 pixels) by a block section  301 . The input video signal segmented into macro blocks is input to a subtracter  302 . The difference from a predicted video signal is calculated to generate a prediction residual error signal. One of the prediction residual error signal and the input video signal from the block section  301  is selected by a mode selection switch  303  and subjected to discrete cosine transformation by a DCT (Discrete Cosine Transformation) section  304 . 
   The DCT coefficient data obtained by the DCT section  304  is quantized by a quantizer section  305 . The signal quantized by the quantizer section  305  is branched to two signals. One signal is variable-length-encoded by a variable-length encoder section  315 . The other signal is sequentially subjected to processing operations by a dequantizer section  306  and IDCT (inverse discrete cosine transformation processing) section  307 , which are opposite to those by the quantizer section  305  and DCT section  304 , and then added, by an adder  308 , to the predicted video signal input through a switch  311 , whereby a local decoded signal is generated. This local decoded signal is stored in a frame memory  309  and input to a motion compensation section  310 . The motion compensation section  310  generates a predictive picture signal and sends necessary information to a mode selector section  312 . 
   The mode selector section  312  selects, one of a macro block for which inter-frame encoding is to be performed and a macro block for which intra-frame encoding is to be performed, on the basis of prediction information P from the motion compensation section  310  in units of macro blocks. More specifically, for intra-frame encoding (INTRA encoding), mode selection switch information M is set to A, and switch information S is set to A. For inter-frame encoding (INTER encoding), the mode selection switch information M is set to B, and the switch information S is set to B. 
   The mode selection switch  303  is switched on the basis of the mode selection switch information M, while the switch  311  is switched on the basis of the switch information S. Modes include the intra mode (INTRA), inter mode (INTER), and non coding mode (NON — CODED). One of these modes is made to correspond to each macro block. More specifically, an INTRA macro block is an image region for intra-frame encoding, an INTER macro block is an image region for inter-frame encoding, and a NOT — CODED macro block is an image region that requires no encoding. 
   In a traffic density analyzer section  400 , encoded information output from a variable-length encoder section  314 , the local decoded signal output from the adder  308  and the local decoded signal of the previous frame output from the frame memory  309  are input to a macro-block moving object determination section  401 . The macro-block moving object determination section  401  determines whether the macro block is a moving object that moves in the screen, as in the first embodiment, and inputs the determination result to a macro-block analyzer section  402 . 
   The macro-block analyzer section  402  performs image analysis for the pixels of the macro block which is determined by the macro-block moving object determination section  401  as a moving object, as in the first embodiment, and sends the analysis result to a specific vehicle estimator section  403  and traffic density estimator section  404 . 
   The specific vehicle estimator section  403  estimates a specific vehicle from a color and shape in the image analysis result for the macro block, as in the first embodiment. The traffic density estimator section  404  also sets a specific region on the screen on the basis of the image analysis result for the macro block, and estimates the traffic density from the velocities and areas of moving objects that pass through the specific region in the image analysis result, as in the first embodiment. The estimation results from the specific vehicle estimator section  403  and traffic density estimator section  404  are input to a specific object synthesis/display section (not shown) and also input to a multiplexer section  315  of a video encoder section  300 . 
   An encode controller section  313  controls an encoder section  317  on the basis of encoding information for the encoder section  317  and the buffer amount of an output buffer  316 . The video encoded data encoded by the variable-length encoder section  314  is multiplexed with the specific vehicle determination result from the specific vehicle estimator section  403  by the multiplexer section  315  and sent to the transmission system or storage medium as encoded data after the transmission rate is smoothed by the output buffer  316 . 
   Referring to  FIG. 8 , the traffic density analyzer section  400  uses the local decoded signal and that of the previous frame from the frame memory  309 . However, the same effect as described above can be obtained even using the input video signal and that of the previous frame. 
   When the video encoding/analyzing apparatus shown in  FIG. 8  is built in the traffic density monitoring system shown in  FIG. 1 , the video encoding/analyzing apparatus is applied to the monitor camera section  1 . 
   As has been described above, according to the present invention, a traffic density analysis apparatus based on an encoded video, which can stably analyze the traffic density at a high speed, can be provided. 
   Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.

Technology Category: 3