Summary

Clone URL:

hg Use ID

Description:

software for automated go games recording

Trending files:

Download:

Download as zip With subrepos

Latest Changes

Laman	891cf60dcb1e	6 years ago	exp: work on stone detection default
Laman	aeca91e58167	6 years ago	exp: image color analysis default
Laman	6f867d8eac54	6 years ago	exp: detecting grid with Hough transform default
Laman	0fd3bebe7462	6 years ago	export sample cells default
Laman	176c678923b7	6 years ago	get stones samples default
Laman	d91db8f73233	6 years ago	annotations: refactored into a separate file default
Laman	ac065d1dfcab	6 years ago	annotations accomodated for multiple boards present default
Laman	28ca21b89e43	6 years ago	fix: returned returns to corners default
Laman	6180b3bd7f3f	6 years ago	generating synthetic samples default
Laman	f125391c937d	6 years ago	corners: order canonization moved to the add method default

readme.md

OneEye

A program to extract moves of a go game from a video and save them to SGF or broadcast them online.

The basic prototype is already working. However, it requires the user to manually mark the board. This is bothersome and more importantly, the same would be required again for any possible movement of the camera or the board. Which is unavoidable.

Position detection

Therefore our current research focuses on automatic position detection. It is planned as a sequence of three stages.

Sansa

First detector approximately locates the board in the picture. It uses SSD (single shot detector) with MobileNet and is working decently.

Examples (downloaded from Flickr under CC0 license):
Sansa example 1

Sansa example 2

Dochi

Then the cropped and normed image is fed to the second detector, designed to return precise grid corners' coordinates. This is currently implemented by a convolutional neural network and obtaining the required precision is a major hurdle to be passed.

Pretty good:
Dochi example 1

Also good, but not enough:
Dochi example 2

Genjo

With grid corners it is not difficult to rectify the image and cut it into tiles, one for each intersection. Then a third stage, Genjo classifier, decides whether the intersection is empty or occupied by a black or white stone. This is currently realized by a sample of pixels voting according to their HSI intensity and it suffices to produce satisfying results. Further improvements should be relatively easy.

Stringing a sequence of board states to a sequence of moves

Base case: we have two correctly recognized positions differing by a single move (single added stone). Easy.

Issues:

illegal positions -> ignorable
positions unreachable from the previous state
- reachable from any past state. (Incorrect states inbetween.) How to pick the correct leaf of such a tree?
- reachable by more than one move. (Lost states inbetween.) Issues with branching factor.
stone shifts
- stone stops being recognized -> fixable manually and even ignorable
- stone is recognized at an empty intersection. It can be occupied later for real. What do?

This is handled by the statebag package and its documentation also states the problem and used solution in precise terms.

﻿OneEye