Japanese ANPR

Vision AI powered Automatic Number Plate Recognition (ANPR) for Japan

Automatic Number Plate Recognition (ANPR), also called Automatic License Plate Recognition (ALPR), refers to an accurate image processing system used for detecting and reading vehicle number plates. It uses an Optical Character Recognition (OCR) component on images of number plates that are captured at high speed, to detect individual characters on the number plate and transforms them into digital data. 

ANPR is, therefore, the underlying technology used to detect a vehicle license / number plate that, in turn, supplies this information to the next stage of computer processing through which the captured information can be interpreted, stored or matched to create an ANPR based application.

ANPR is being used by law enforcement agencies across countries like the UK, Australia, Germany, France, Denmark, Japan and others for automatic toll collection, traffic law enforcement, parking lot access control, and road traffic monitoring, journey time analysis, bus lane enforcement among others. 

Japan has been fast in deploying ANPR systems in patrol cars, helicopters and fixed in strategically important areas. In Japan, fixed ANPR systems are expected to reach a market size of US$44.4 Billion by the year 2025*.  

In this blog, we outline how a Japanese license plate is detected and the characters in the license plate recognized. The license plate detection is based on semantic segmentation with a Resnet-type model and character recognition is based on a classifier network. Japanese license plates have certain special features which have to be studied as a first step.

 

Special Features of Japanese License plates

The Japanese license plate consists of 4 main sub portions . The following figure depicts each of the sub regions.

 

Japanese Licence plate format

  Fig 1. A Japanese License plate format

Also different color license plates indicate the engine capacity of the vehicle . The following figure describes different colors and corresponding engine capacity.


Color Specification of Japanese Number Plate

Fig.2 Color specifications of a Japanese License Plate

The top line contains the name of the issuing office and a vehicle class code. The bottom line contains a hiragana character and a four-digit serial number divided into two groups of two digits separated by a hyphen. Any leading zeros are replaced by centered dots.

 

Dataset preparation and Labeling

The dataset is created using images from a variety of sources. The following site provides a representative set. [Link]

The training results yield maximum accuracy only if the labels of the region of interest are correct. To ensure this, tight labeling is required. The collected images are then labeled using the LabelMe application. These images and corresponding xml files are used for training purposes.

 

License Plate Detection and Classification

 

Vehicle detection pipeline
Fig.3 Vehicle Detection Pipeline

 

We describe the above pipeline with respect to a sample input image:

YOLO cropping


Fig.4 Raw input image

The first step in ANPR is to detect and isolate the vehicle from the background, from the raw input images. Here we have used the Tiny YOLO (You Only Look Once) v3 model for the purpose of object detection. Reasoning behind choosing YOLO is due to it’s fast, accurate and multi-scale predictions. An important criteria here is that it is a real-time object detection system. The objects we are interested in range from cars, buses to trucks. Detections such as roads, hills, people and the like are discarded as they aren’t of interest in our use case. Using Tiny YOLO, we extract the vehicle crop.

 

Cropped Image by Yolo
Fig.5 Vehicle crop generated using YOLO

 

License Plate Detection module
The vehicle crop is passed onto a semantic segmentation model, which in turn extracts the number plate region. These number plate bounding regions can be stored in suitable format such as ((x1, y1), (x2, y2)) or (x, y, w, h) in a json file.

Licence Plate crop
Fig.6 License Plate crop


License Plate Crops
Semantic segmentation also generates relevant masks for area, color, digit and purpose. This semantic segmentation model is trained on the Japanese License Plate dataset so as to generate these masks. Similar to the previous step, here too the masks are stored in a suitable format in a json file. 


Fig.7 Masks for area, color, digit and purpose


OCR prediction
The next stage requires us to apply Optical Character Recognition (OCR) onto these mask areas. This stage returns the predictions of features of interest on the specific number plate. These predictions are based on the following classes:
Color
[‘black’, ‘white’, ‘green’, ‘yellow’]
Area
[‘shizuoka’, ‘fukuoka’, ‘fukushima’, ‘gifu’, ‘gunma’, ‘hiroshima’, ‘kanazawa’, ‘kitami’, ‘kochi’, ‘nilgata’, ‘obihiro’, ‘oita’, ‘tokushima’, ‘toyama’, ‘utsunomia’, ‘okayama’, ‘sappora’, ‘sendai’, ‘numazu’, ‘chiba’, ‘yamanashi’, ‘tama’, ‘osaka’, ‘yokohama’, ‘maebashi’, ‘nerima’, ‘wakayama’, ‘kobe’, ‘miyazaki’, ‘saitama’, ‘kumagaya’, ‘shinagawa’, ‘nara’, ‘adachi’, ‘kyoto’, ‘naniwa’, ‘himeji’, ‘kawasaki’]
Purpose
[’13’, ‘2’, ’20’, ‘7’, ‘1’, ’17’, ’10’, ’25’, ’12’, ’18’, ’21’, ‘5’, ‘4’, ’24’, ’23’, ’16’, ’15’, ’22’, ’19’, ‘3’, ‘8’, ‘9’, ’14’, ‘6’, ’11’, ’26’, ’27’, ’28’]
Digit
[‘2’, ‘7’, ’00’, ‘1’, ’90’, ‘0’, ‘5’, ‘4’, ‘3’, ‘8’, ‘9’, ‘6’, ’13’, ’18’, ’22’, ’23’, ’33’, ‘100’]

Below are the predictions generated by our pipeline for the sample test image:

Predicted Console Result
Fig.8 Predicted console result

 

 

Annotated Result Number Plate
Fig.9 Annotated result number plate

 

 

Conclusion

This article introduces our deep-learning based ANPR pipeline that is capable of automatically detecting vehicles, cropping out their license plates and recognizing Japanese characters and all other relevant fields. The production version of our ANPR software can integrate with cost-effective IP or web cameras and perform real-time automatic plate reading using cost effective compute systems – thus allowing their deployment in a host of practical applications.  

For more use cases of our Vision AI powered software, read our blogs on Automatic Container Code Detection, Face Mask and Attire detection and Automated Tyre Defect Detection

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