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SPEI vs NDVI MODIS Growth Season.js
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SPEI vs NDVI MODIS Growth Season.js
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////////////////////////////////////////////////////////////////////////////
// This script uses MODIS 1km NDVI product and it is spatially //
// correlate with SPEI calculated from NOAH Global Land Assimulation //
// System data. It will display and export the correlation map of SPEI vs //
// three months sum of NDVI anomalies. //
// Note: SPEIxMonth in selected month vs NDVI three month anomalies //
//------------------------------------------------------------------------//
// For fast global study //
// Contact: Shunan Feng (冯树楠): fsn.1995@gmail.com //
////////////////////////////////////////////////////////////////////////////
//------------------------------------------------------------------------//
// Preparation //
//------------------------------------------------------------------------//
// study time range
var year_start = 2001; // MODIS NDVI 2000-02-18T00:00:00 - Present
var year_end = 2018;
var month_start = 1;
var month_end = 12;
// define the growth season (selected month of spei) here
var speim = 4;// month of spei
var date_start = ee.Date.fromYMD(year_start, 1, 1);
var date_end = ee.Date.fromYMD(year_end, 12, 31);
var years = ee.List.sequence(year_start, year_end);// time range of years
var months = ee.List.sequence(month_start, month_end);// time range of months
// change the month lag here, e.g. no lag is 0,-1 is one month lag,-2 is 2 month lag
var lagflag = -1;
// The default setting will correlate correlate 2 month time scale of SPEI(SPEI2m)
// in April with one month lag of three month (May to July) sum of NDVI anomalies.
//------------------------------------------------------------------------//
// Datainput //
//------------------------------------------------------------------------//
// load MODIS NDVI 2000-02-18T00:00:00 - Present
var ndvi = ee.ImageCollection('MODIS/006/MOD13A2')
.filterDate(date_start, date_end)
.select('NDVI');
var spei1m = ee.ImageCollection("users/fsn1995/spei1m_noah");
var spei2m = ee.ImageCollection("users/fsn1995/spei2m_noah");
var spei3m = ee.ImageCollection("users/fsn1995/spei3m_noah");
var spei4m = ee.ImageCollection("users/fsn1995/spei4m_noah");
var spei5m = ee.ImageCollection("users/fsn1995/spei5m_noah");
var spei6m = ee.ImageCollection("users/fsn1995/spei6m_noah");
var spei7m = ee.ImageCollection("users/fsn1995/spei7m_noah");
var spei8m = ee.ImageCollection("users/fsn1995/spei8m_noah");
var spei9m = ee.ImageCollection("users/fsn1995/spei9m_noah");
var spei10m = ee.ImageCollection("users/fsn1995/spei10m_noah");
var spei11m = ee.ImageCollection("users/fsn1995/spei11m_noah");
var spei12m = ee.ImageCollection("users/fsn1995/spei12m_noah");
// select the time scale of spei here
var spei = spei3m;
// load land cover data
var lucc = ee.Image('USGS/NLCD/NLCD2011').select('landcover');
// monthly average NDVI
// sytstem time is set as 1st of each month
var NDVI_monthlyave = ee.ImageCollection.fromImages(
years.map(function (y) {
return months.map(function(m) {
var vi = ndvi.select('NDVI')
.filter(ee.Filter.calendarRange(y, y, 'year'))
.filter(ee.Filter.calendarRange(m, m, 'month'))
.mean()
.rename('NDVIm');
return vi.set('year', y)
.set('month', m)
.set('system:time_start', ee.Date.fromYMD(y, m, 1));
});
}).flatten()
);
// 20yr monthly average NDVI
var NDVI_30yrave = ee.ImageCollection.fromImages(
months.map(function (m) {
var vi = ndvi.select('NDVI')
.filter(ee.Filter.calendarRange(m, m, 'month'))
.mean()
.rename('NDVIy');
return vi.set('month', m);
}).flatten()
);
// print(NDVI_30yrave);
// NDVI anomaly = monthly average NDVI - 30yr monthly average NDVI
// NDVI monthly anomaly
var monthfilter = ee.Filter.equals({
leftField: 'month',
rightField: 'month',
});
var monthlink = ee.Join.saveFirst({
matchKey: 'match',
});
var NDVI_monthlink = ee.ImageCollection(monthlink.apply(NDVI_monthlyave,NDVI_30yrave,monthfilter))
.map(function(image) {
return image.addBands(image.get('match'));
});
var addNDVI_anomaly = function(image) {
var anomaly = image.expression(
'b1-b2',
{
b1: image.select('NDVIm'),
b2: image.select('NDVIy'),
}
).rename('NDVI_anomaly');
return image.addBands(anomaly);
};
var NDVI_anomaly = NDVI_monthlink.map(addNDVI_anomaly);
//------------------------------------------------------------------------//
// Lag //
//------------------------------------------------------------------------//
// lag is achieved by shifting the date of the data
var addLagm = function(image) {
var lagm = ee.Date(image.get('system:time_start')).advance(lagflag,'month');
return image.set({'lagm': lagm});
};
// below is to compute ndvi three month anomaly
var addLag0m = function(image) {
var lagm = ee.Date(image.get('system:time_start')).advance(0,'month');
return image.set({'lagm': lagm});
};
var addLag1m = function(image) {
var lagm = ee.Date(image.get('system:time_start')).advance(-1,'month');
return image.set({'lagm': lagm});
};
var addLag2m = function(image) {
var lagm = ee.Date(image.get('system:time_start')).advance(-2,'month');
return image.set({'lagm': lagm});
};
// compute three month sum ndvi anomaly
var NDVI0 = NDVI_anomaly.select('NDVI_anomaly').map(addLag0m);
var NDVI1 = NDVI_anomaly.select('NDVI_anomaly').map(addLag1m);
var NDVI2 = NDVI_anomaly.select('NDVI_anomaly').map(addLag2m);
var lagFilter = ee.Filter.equals({
leftField: 'lagm',
rightField: 'lagm',
});
var lagLink = ee.Join.saveFirst({
matchKey: 'match',
});
var NDVI_threeMonthAnomaly = ee.ImageCollection(lagLink.apply(NDVI0.select('NDVI_anomaly'),
NDVI1.select('NDVI_anomaly'),lagFilter))
.map(function(image) {
return image.addBands(image.get('match'));
});
var NDVI_threeMonthAnomaly = ee.ImageCollection(lagLink.apply(NDVI_threeMonthAnomaly,
NDVI2.select('NDVI_anomaly'),lagFilter))
.map(function(image) {
return image.addBands(image.get('match'));
});
var NDVI_anomaly_sum = NDVI_threeMonthAnomaly.map(function(image) {
return image.addBands(
image.expression('a1 + b1 + c1', {
a1: image.select('NDVI_anomaly'),
b1: image.select('NDVI_anomaly_1'),
c1: image.select('NDVI_anomaly_2'),
}).rename('NDVI_anomalySum'));
});
var NDVI_anomSumMLag = NDVI_anomaly_sum.select('NDVI_anomalySum')
.map(addLagm)
.filterMetadata('month','equals', speim);
//------------------------------------------------------------------//
// This part compares NDVI anomalies with spei2m computed from NOAH //
// Global land assimulation system //
//------------------------------------------------------------------//
var speiSet = spei.map(function(image) {
return image.set('date', image.date());
});
var timescaleFilter = ee.Filter.equals({
leftField: 'lagm',
rightField: 'date',
});
// print(speiSet,'speiSet');
var NDVI3mLag_spei = ee.ImageCollection(lagLink.apply(NDVI_anomSumMLag.select('NDVI_anomalySum'),
speiSet.select('b1'),timescaleFilter))
.map(function(image) {
return image.addBands(image.get('match'));
});
var corrmap = NDVI3mLag_spei.reduce(ee.Reducer.pearsonsCorrelation());
// //.addBands(lucc.select('landcover').rename('lucc'));
// // var corrmap = NDVI_spei.reduce(ee.Reducer.spearmansCorrelation()).clip(roi);
// // .addBands(lucc.select('landcover').rename('lucc'));
var corrParams = {min: -1, max: 1, palette: ['red','white', 'green']};
Map.addLayer(corrmap.select('correlation'), corrParams, 'Correlation Map');
Export.image.toDrive({
image: corrmap,
folder: 'growth',
description: 'Correlation map of spei with ndvi anomalies',
scale: 10000,
// region: roi // If not specified, the region defaults to the viewport at the time of invocation
});
// var options = {
// // lineWidth: 1,
// // pointSize: 2,
// hAxis: {title: 'R and P value'},
// vAxis: {title: 'Correlation Coefficient'},
// title: 'Correlation map average'
// };
// var chart = ui.Chart.image.byClass(
// corrmap, 'lucc', roi, ee.Reducer.mean(), 100000, lucc.get('landcover_class_names')
// ).setOptions(options);
// print(chart);