The significance of image compression in plant phenotyping applications.

We are currently witnessing an increasingly higher throughput in image-based plant phenotyping experiments. The majority of imaging data are collected using complex automated procedures and are then post-processed to extract phenotyping-related information. In this article, we show that the image compression used in such procedures may compromise phenotyping results and this needs to be taken into account. We use three illuminating proof-of-concept experiments that demonstrate that compression (especially in the most common lossy JPEG form) affects measurements of plant traits and the errors introduced can be high. We also systematically explore how compression affects measurement fidelity, quantified as effects on image quality, as well as errors in extracted plant visual traits. To do so, we evaluate a variety of image-based phenotyping scenarios, including size and colour of shoots, leaf and root growth. To show that even visual impressions can be used to assess compression effects, we use root system images as examples. Overall, we find that compression has a considerable effect on several types of analyses (albeit visual or quantitative) and that proper care is necessary to ensure that this choice does not affect biological findings. In order to avoid or at least minimise introduced measurement errors, for each scenario, we derive recommendations and provide guidelines on how to identify suitable compression options in practice. We also find that certain compression choices can offer beneficial returns in terms of reducing the amount of data storage without compromising phenotyping results. This may enable even higher throughput experiments in the future.

[1]  Christian Klukas,et al.  Integrated Analysis Platform: An Open-Source Information System for High-Throughput Plant Phenotyping1[C][W][OPEN] , 2014, Plant Physiology.

[2]  Li Wu,et al.  DYNAMICS OF SEED GERMINATION , SEEDLING GROWTH AND PHYSIOLOGICAL RESPONSES OF SWEET CORN UNDER PEG-INDUCED WATER STRESS , 2017 .

[3]  A. Rolland-Lagan,et al.  Quantifying Shape Changes and Tissue Deformation in Leaf Development1[C][W][OPEN] , 2014, Plant Physiology.

[4]  Jeffrey W. White,et al.  Development and evaluation of a field-based high-throughput phenotyping platform. , 2013, Functional plant biology : FPB.

[5]  T. Shiina,et al.  A Scalable Open-Source Pipeline for Large-Scale Root Phenotyping of Arabidopsis[W][OPEN] , 2014, Plant Cell.

[6]  Debargha Mukherjee,et al.  The latest open-source video codec VP9 - An overview and preliminary results , 2013, 2013 Picture Coding Symposium (PCS).

[7]  Christoph Briese,et al.  Plant Shoot Image Segmentation using Colour Features and Support Vector Machines , 2013 .

[8]  Yaowu Xu,et al.  Technical overview of VP8, an open source video codec for the web , 2011, 2011 IEEE International Conference on Multimedia and Expo.

[9]  Nathan D. Miller,et al.  Image analysis is driving a renaissance in growth measurement. , 2013, Current opinion in plant biology.

[10]  Tim Brown,et al.  High-resolution, time-lapse imaging for ecosystem-scale phenotyping in the field. , 2012, Methods in molecular biology.

[11]  Ulrich Schurr,et al.  Dynamics of leaf and root growth: endogenous control versus environmental impact. , 2005, Annals of botany.

[12]  Touradj Ebrahimi,et al.  Perceptual Video Compression: A Survey , 2012, IEEE Journal of Selected Topics in Signal Processing.

[13]  J. Weickert,et al.  Lucas/Kanade meets Horn/Schunck: combining local and global optic flow methods , 2005 .

[14]  Alessandro Ferrero,et al.  Camera as the instrument: the rising trend of vision based measurement , 2014, IEEE Instrumentation & Measurement Magazine.

[15]  N. Bernstein,et al.  The Determination of Relative Elemental Growth Rate Profiles from Segmental Growth Rates (A Methodological Evaluation) , 1997, Plant physiology.

[16]  Antonio Ortega,et al.  Rate-distortion methods for image and video compression , 1998, IEEE Signal Process. Mag..

[17]  Khalid Sayood,et al.  Introduction to Data Compression , 1996 .

[18]  Abhiram Das,et al.  Image-Based High-Throughput Field Phenotyping of Crop Roots1[W][OPEN] , 2014, Plant Physiology.

[19]  K. Chenu,et al.  PHENOPSIS, an automated platform for reproducible phenotyping of plant responses to soil water deficit in Arabidopsis thaliana permitted the identification of an accession with low sensitivity to soil water deficit. , 2006, The New phytologist.

[20]  Hanna Cwiek On Minimum Reporting Requirements and Standard Formatting of Plant Phenotypic Data , 2014 .

[21]  R. A. Leibler,et al.  On Information and Sufficiency , 1951 .

[22]  Xavier Draye,et al.  An online database for plant image analysis software tools , 2013, Plant Methods.

[23]  Ulrich Schurr,et al.  Future scenarios for plant phenotyping. , 2013, Annual review of plant biology.

[24]  Steve A. Kay,et al.  Daily Changes in Temperature, Not the Circadian Clock, Regulate Growth Rate in Brachypodium distachyon , 2014, PloS one.

[25]  Uwe Rascher,et al.  Remote chlorophyll fluorescence measurements with the laser-induced fluorescence transient approach. , 2012, Methods in molecular biology.

[26]  Sotirios A. Tsaftaris,et al.  Application-aware image compression for low cost and distributed plant phenotyping , 2013, 2013 18th International Conference on Digital Signal Processing (DSP).

[27]  M. M. Christ,et al.  Dynamics of seedling growth acclimation towards altered light conditions can be quantified via GROWSCREEN: a setup and procedure designed for rapid optical phenotyping of different plant species. , 2007, The New phytologist.

[28]  C. Granier,et al.  Phenotyping and beyond: modelling the relationships between traits. , 2014, Current opinion in plant biology.

[29]  Lutz Plümer,et al.  Low-Cost 3D Systems: Suitable Tools for Plant Phenotyping , 2014, Sensors.

[30]  Carme Torras,et al.  Robotized Plant Probing: Leaf Segmentation Utilizing Time-of-Flight Data , 2013, IEEE Robotics & Automation Magazine.

[31]  M. Tester,et al.  High-throughput shoot imaging to study drought responses. , 2010, Journal of experimental botany.

[32]  Hanno Scharr,et al.  Annotated Image Datasets of Rosette Plants , 2014 .

[33]  Mathias Wien,et al.  High Efficiency Video Coding: Coding Tools and Specification , 2014 .

[34]  Frederik Coppens,et al.  High-resolution time-resolved imaging of in vitro Arabidopsis rosette growth. , 2014, The Plant journal : for cell and molecular biology.

[35]  D. Inzé,et al.  Cell to whole-plant phenotyping: the best is yet to come. , 2013, Trends in plant science.

[36]  Yongdong Zhang,et al.  High Efficiency Video Coding: High Efficiency Video Coding , 2014 .

[37]  Aggelos K. Katsaggelos,et al.  Low-Complexity Tracking-Aware H.264 Video Compression for Transportation Surveillance , 2011, IEEE Transactions on Circuits and Systems for Video Technology.

[38]  Hanno Scharr,et al.  Spatio-temporal quantification of differential growth processes in root growth zones based on a novel combination of image sequence processing and refined concepts describing curvature production. , 2008, The New phytologist.

[39]  B. S. Manjunath,et al.  The iPlant Collaborative: Cyberinfrastructure for Plant Biology , 2011, Front. Plant Sci..

[40]  C. Christopoulos,et al.  Efficient methods for encoding regions of interest in the upcoming JPEG2000 still image coding standard , 2000, IEEE Signal Processing Letters.

[41]  P. Benfey,et al.  Advanced imaging techniques for the study of plant growth and development. , 2014, Trends in plant science.

[42]  Dirk Walther,et al.  Data management pipeline for plant phenotyping in a multisite project. , 2012, Functional plant biology : FPB.

[43]  Beverly D. Sanford,et al.  DEVELOPMENT AND EVALUATION IN THE FIELD , 1993 .

[44]  L. R. Dice Measures of the Amount of Ecologic Association Between Species , 1945 .

[45]  Hans-Hellmut Nagel,et al.  Optical Flow Estimation: Advances and Comparisons , 1994, ECCV.

[46]  A. Bovik,et al.  Image quality assessment , 2019, Machine Learning for Tomographic Imaging.

[47]  Gary J. Sullivan,et al.  Overview of the High Efficiency Video Coding (HEVC) Standard , 2012, IEEE Transactions on Circuits and Systems for Video Technology.

[48]  Eero P. Simoncelli,et al.  Image quality assessment: from error visibility to structural similarity , 2004, IEEE Transactions on Image Processing.

[49]  H. Scharr,et al.  GROWSCREEN-Rhizo is a novel phenotyping robot enabling simultaneous measurements of root and shoot growth for plants grown in soil-filled rhizotrons. , 2012, Functional plant biology : FPB.

[50]  Guillermo Sapiro,et al.  The LOCO-I lossless image compression algorithm: principles and standardization into JPEG-LS , 2000, IEEE Trans. Image Process..

[51]  H. Poorter,et al.  Phenotyping plants: genes, phenes and machines. , 2012, Functional plant biology : FPB.

[52]  Sotirios A. Tsaftaris,et al.  Image-based plant phenotyping with incremental learning and active contours , 2014, Ecol. Informatics.

[53]  Martin J. Murillo,et al.  Long-Distance Telecommunication in Remote Poor Areas: From Partnerships and Implementation to Sustainability , 2015, IEEE Technology and Society Magazine.

[54]  A. Greenberg,et al.  Next-generation phenotyping: requirements and strategies for enhancing our understanding of genotype–phenotype relationships and its relevance to crop improvement , 2013, Theoretical and Applied Genetics.

[55]  É. Hideg,et al.  Leaf hue measurements: a high-throughput screening of chlorophyll content. , 2012, Methods in molecular biology.

[56]  Sotirios A. Tsaftaris,et al.  Unsupervised and supervised approaches to color space transformation for image coding , 2014, 2014 IEEE International Conference on Image Processing (ICIP).

[57]  Hanno Scharr,et al.  Image Analysis: The New Bottleneck in Plant Phenotyping [Applications Corner] , 2015, IEEE Signal Processing Magazine.

[58]  Touradj Ebrahimi,et al.  The JPEG 2000 still image compression standard , 2001, IEEE Signal Process. Mag..

[59]  Ulrich Schurr,et al.  Primary root growth: a biophysical model of auxin-related control. , 2005, Functional plant biology : FPB.

[60]  M. Tester,et al.  Phenomics--technologies to relieve the phenotyping bottleneck. , 2011, Trends in plant science.

[61]  B. Jähne,et al.  Quantitative analysis of the local rates of growth of dicot leaves at a high temporal and spatial resolution, using image sequence analysis , 1998 .

[62]  I. Xenarios,et al.  Measuring the diurnal pattern of leaf hyponasty and growth in Arabidopsis - a novel phenotyping approach using laser scanning. , 2012, Functional plant biology : FPB.

[63]  Joost T. van Dongen,et al.  Diurnal Changes of Polysome Loading Track Sucrose Content in the Rosette of Wild-Type Arabidopsis and the Starchless pgm Mutant1[W][OA] , 2013, Plant Physiology.