Double-cylinder cultivation container imaging system

Abstract

The invention relates to a double-cylinder cultivation container imaging system which comprises a turnover line body, a first photographing platform and a second photographing platform, the turnover line body is used for conveying double-cylinder cultivation containers, and the first photographing platform and the second photographing platform are arranged on the two sides of the turnover line body in the length direction respectively and used for imaging root systems on the inner walls of the double-cylinder cultivation containers; the first photographing platform and the second photographing platform are each provided with rotary photographing devices and pallet fork assemblies, the rotary photographing devices on the first photographing platform correspond to the pallet fork assemblies on the second photographing platform in a one-to-one mode, the pallet fork assemblies on the first photographing platform correspond to the rotary photographing devices on the second photographing platform in a one-to-one mode, and the pallet fork assemblies are used for supporting the double-cylinder cultivation containers on the turnover line body and placing the double-cylinder cultivation containers on the corresponding rotary photographing devices or supporting the double-cylinder cultivation containers on the corresponding rotary photographing devices and placing the double-cylinder cultivation containers on the turnover line body. The high-flux and automatic real-time monitoring and acquisition of the root systems in the double-cylinder cultivation containers are realized.

Description

technical field [0001] The invention relates to a root system dynamic growth imaging system, in particular to a double-cylindrical cultivation container imaging system. Background technique [0002] The research on the interaction mechanism of gene-environment-phenotype requires the help of modern information technology with big data as the core. With the improvement of the efficiency of sequencing technology and the reduction of cost, the crop genome data is constantly growing and perfecting; however, the current phenotypic information acquisition technology lags behind, which makes it unable to match the huge genomics data, which seriously hinders the breeding process. The construction of automated equipment for non-destructive, efficient, and systematic collection of phenome information has become a hot issue that needs to be solved urgently in agronomy, plant physiology, and genetics and breeding. [0003] In recent years, many academic institutions and companies have d...

AI Technical Summary

Problems solved by technology

The GROWSCREEN-Rhizo developed by the Ulyssey Research Center in Germany can image the root system in the narrow root box, but this method can only obtain part of the fragmented root phenotype information, and when cultivating crops with large root systems such as fibrous root crops corn, etc. , the narrow root box limits the growth space of the root system, resulting in serious overlapping of the root system in the imaging window, and the acquired root system image loses more root phenotype information

[0004] To sum up, the existing root phenotyping platform can only obtain small plant root phenotype information, and there are generally problems such as low throughput, high equipment cost, and low space utilization.

In addition, the existing phenotyping platform cannot obtain high-quality root images of fibrous root crops

The throughput expansion of the conveyor belt-based transportation method is easy to realize, but the cost of supporting equipment is high, especially for the ultra-large crop phenotyping platform, the cost of all configurations of the conveyor system is extremely high

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