农业工程学报
農業工程學報
농업공정학보
2015年
1期
294-302
,共9页
岳学军%全东平%洪添胜%王健%瞿祥明%甘海明
嶽學軍%全東平%洪添勝%王健%瞿祥明%甘海明
악학군%전동평%홍첨성%왕건%구상명%감해명
叶绿素%主成分分析%无损检测%高光谱%柑橘叶片%支持向量机回归%偏最小二乘回归
葉綠素%主成分分析%無損檢測%高光譜%柑橘葉片%支持嚮量機迴歸%偏最小二乘迴歸
협록소%주성분분석%무손검측%고광보%감귤협편%지지향량궤회귀%편최소이승회귀
chlorophyll%principle component analysis%nondestructive examination%hyperspectrum%citrus leaves%support vector regression%partial least square regression
针对柑橘叶片叶绿素含量的传统化学检测,不仅耗时长且损伤柑橘叶片,还依赖检测者实操技术,无法集成于精细农业中变量喷施农机具的诸多弊端,该文探讨快速无损检测柑橘叶片叶绿素含量方法。以117棵园栽萝岗甜橙树为研究对象,选用ASD FieldSpec 3光谱仪对萌芽期、稳果期、壮果促梢期、采果期共4个生长时期的柑橘叶片进行高光谱反射率采集,并同步采用分光光度法测得叶片的叶绿素含量;以原始光谱及其变换形式作为模型输入矢量,分别在主成分分析(principle component analysis,PCA)降维的基础上利用支持向量机回归(support vector regression,SVR)算法和在小波去噪的基础上利用偏最小二乘回归(partial least square regression,PLSR)算法对柑橘叶片叶绿素含量进行建模预测,全生长期整体建模的校正集和验证集最佳模型决定系数 R2分别为0.8713和0.8670,均方根误差 RMSE (root-mean-square error)分别为0.1517和0.1544,试验结果表明,高光谱可快速无损地对柑橘叶片叶绿素含量进行精确的定量检测,为柑橘不同生长期的营养监测提供理论依据。
針對柑橘葉片葉綠素含量的傳統化學檢測,不僅耗時長且損傷柑橘葉片,還依賴檢測者實操技術,無法集成于精細農業中變量噴施農機具的諸多弊耑,該文探討快速無損檢測柑橘葉片葉綠素含量方法。以117棵園栽蘿崗甜橙樹為研究對象,選用ASD FieldSpec 3光譜儀對萌芽期、穩果期、壯果促梢期、採果期共4箇生長時期的柑橘葉片進行高光譜反射率採集,併同步採用分光光度法測得葉片的葉綠素含量;以原始光譜及其變換形式作為模型輸入矢量,分彆在主成分分析(principle component analysis,PCA)降維的基礎上利用支持嚮量機迴歸(support vector regression,SVR)算法和在小波去譟的基礎上利用偏最小二乘迴歸(partial least square regression,PLSR)算法對柑橘葉片葉綠素含量進行建模預測,全生長期整體建模的校正集和驗證集最佳模型決定繫數 R2分彆為0.8713和0.8670,均方根誤差 RMSE (root-mean-square error)分彆為0.1517和0.1544,試驗結果錶明,高光譜可快速無損地對柑橘葉片葉綠素含量進行精確的定量檢測,為柑橘不同生長期的營養鑑測提供理論依據。
침대감귤협편협록소함량적전통화학검측,불부모시장차손상감귤협편,환의뢰검측자실조기술,무법집성우정세농업중변량분시농궤구적제다폐단,해문탐토쾌속무손검측감귤협편협록소함량방법。이117과완재라강첨등수위연구대상,선용ASD FieldSpec 3광보의대맹아기、은과기、장과촉소기、채과기공4개생장시기적감귤협편진행고광보반사솔채집,병동보채용분광광도법측득협편적협록소함량;이원시광보급기변환형식작위모형수입시량,분별재주성분분석(principle component analysis,PCA)강유적기출상이용지지향량궤회귀(support vector regression,SVR)산법화재소파거조적기출상이용편최소이승회귀(partial least square regression,PLSR)산법대감귤협편협록소함량진행건모예측,전생장기정체건모적교정집화험증집최가모형결정계수 R2분별위0.8713화0.8670,균방근오차 RMSE (root-mean-square error)분별위0.1517화0.1544,시험결과표명,고광보가쾌속무손지대감귤협편협록소함량진행정학적정량검측,위감귤불동생장기적영양감측제공이론의거。
Traditional methods of obtaining chlorophyll content of citrus leaves require grinding citrus leaves and applying chemical titrations, which would be harmful to citrus trees and time-consuming. Besides, it's difficult to integrate those chemical methods into variable spraying system as a feedback subsystem. In this paper, we discuss several rapid and non-destructive methods in obtaining chlorophyll content of citrus leaves by using hyperspectral analysis system. Hyperspectral technology obtains synchronously spectrum in continuous space, where we can derive crop growth information visually in a non-destructive way. In this paper, the modeling of chlorophyll content of citrus leaves based on the hyperspectrum was discussed. Field experiments were conducted on 117 planted Luogang citrus trees in the Crab Village of Luogang District, Guangzhou City, Guangdong Province. Hyperspectral reflectance and chlorophyll content of citrus leaves were measured by spectrometer (ASD FieldSpec 3) and traditional spectrophotometry, respectively, during four different growth periods corresponding to germination period, stability period, bloom period and harvesting period. In this way, each sample was presented as an instance-labeled pair, where a high-dimensional vector was regarded as the descriptor along with the measured value of chlorophyll content. All the collected samples constituted a large-scale dataset with totally 468 tuples, 80% of which were utilized as the training set and remaining 20% as the testing set. The model constructed relied on the training set and the testing set was evaluated respectively. Using original spectrum and its transformations as input vector, two models, support vector regression (SVR) based on principle component analysis (PCA) and partial least square regression (PLSR) based on the wavelet denoising were adopted, where PCA was adopted for dimension reduction and the wavelet denoising technique removed high-frequency noise. The two models (SVR and PLSR) were then applied to the final regression analysis for predicting chlorophyll content. The best coefficient of determination (R2) of the calibration set and a validation set of the entire growth period were up to 0.8713 and 0.8670, the root-mean-square error (RMSE) was 0.1517 and 0.1544 respectively. Some main conclusions were obtained:first, when the original reflectance spectrum was used as the input vector and the energy ratio remained 96% for PCA in germination period and stability period, 99% for PCA in bloom period, harvesting period and the whole growth period, SVR with the radial basis function (RBF) as the kernel function achieved the best performance. Second, the wavelet denoising for hyperspectrum data could improve the model performance to some extent. When“sym8”was used as the wavelet basis function,“rigrsure”as the threshold selection,“sln”for rescaling using a single estimation of level noise based on first-level coefficients as the threshold rescaling project and the decomposition layer was 5, PLSR achieved the best result in this research and the coefficient of determination of calibration set and the validation set of the whole growth period were up to 0.8706 and 0.8531, which increased by 8.3%and 9.3%compared with the model without the wavelet denoising. Third, comparative tests between our best model and other models demonstrate the validity and robustness of the two models we derived. Further experimental results revealed that these two models were superior to principle component regression (PCR), stepwise multiple linear regression (SMLR) and back propagation (BP) neural networks. Finally, hyperspectral technology could obtain accurate chlorophyll content of citrus leaves rapidly, quantitatively and non-destructively, our research may provide a theoretical basis for nutrition surveillance of citrus growth.
