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重み付けされた削減
コレクションでコンテンツを整理
必要に応じて、コンテンツの保存と分類を行います。
デフォルトでは、画像に適用されるリデューサーは、マスク値に応じて入力に重み付けを行います。これは、clip() などのオペレーションによって作成された小数ピクセルのコンテキストで関連します。この動作を調整するには、リデューサーで unweighted() を呼び出します。重み付けなしの減算を使用すると、リージョン内のすべてのピクセルに同じ重みが強制されます。次の例は、ピクセル重み付けがレジューサーの出力にどのように影響するかを示しています。
コードエディタ(JavaScript)
// Load a Landsat 8 input image.
var image = ee.Image('LANDSAT/LC08/C02/T1/LC08_044034_20140318');
// Create an arbitrary region.
var geometry = ee.Geometry.Rectangle(-122.496, 37.532, -121.554, 37.538);
// Make an NDWI image. It will have one band named 'nd'.
var ndwi = image.normalizedDifference(['B3', 'B5']);
// Compute the weighted mean of the NDWI image clipped to the region.
var weighted = ndwi.clip(geometry)
.reduceRegion({
reducer: ee.Reducer.mean(),
geometry: geometry,
scale: 30})
.get('nd');
// Compute the UN-weighted mean of the NDWI image clipped to the region.
var unweighted = ndwi.clip(geometry)
.reduceRegion({
reducer: ee.Reducer.mean().unweighted(),
geometry: geometry,
scale: 30})
.get('nd');
// Observe the difference between weighted and unweighted reductions.
print('weighted:', weighted);
print('unweighted', unweighted);
Python の設定
Python API とインタラクティブな開発で geemap を使用する方法については、
Python 環境のページをご覧ください。
import ee
import geemap.core as geemap
Colab(Python)
# Load a Landsat 8 input image.
image = ee.Image('LANDSAT/LC08/C02/T1/LC08_044034_20140318')
# Create an arbitrary region.
geometry = ee.Geometry.Rectangle(-122.496, 37.532, -121.554, 37.538)
# Make an NDWI image. It will have one band named 'nd'.
ndwi = image.normalizedDifference(['B3', 'B5'])
# Compute the weighted mean of the NDWI image clipped to the region.
weighted = (
ndwi.clip(geometry)
.reduceRegion(reducer=ee.Reducer.mean(), geometry=geometry, scale=30)
.get('nd')
)
# Compute the UN-weighted mean of the NDWI image clipped to the region.
unweighted = (
ndwi.clip(geometry)
.reduceRegion(
reducer=ee.Reducer.mean().unweighted(), geometry=geometry, scale=30
)
.get('nd')
)
# Observe the difference between weighted and unweighted reductions.
display('weighted:', weighted)
display('unweighted', unweighted)
結果の違いは、レジューサーで unweighted() を呼び出した結果、リージョンの端のピクセルが重み 1 を受け取ったことが原因です。
明示的に重み付けされた出力を取得するには、レジューサーで呼び出される splitWeights() を使用して重みを明示的に設定することをおすすめします。splitWeights() で変更された Reducer は 2 つの入力を取ります。2 番目の入力は重みです。次の例は、雲スコア(雲が多いほど重みが低い)で重み付けされたリージョンの正規化植生指数(NDVI)の重み付け平均を計算する splitWeights() を示しています。
コードエディタ(JavaScript)
// Load an input Landsat 8 image.
var image = ee.Image('LANDSAT/LC08/C02/T1_TOA/LC08_186059_20130419');
// Compute cloud score and reverse it such that the highest
// weight (100) is for the least cloudy pixels.
var cloudWeight = ee.Image(100).subtract(
ee.Algorithms.Landsat.simpleCloudScore(image).select(['cloud']));
// Compute NDVI and add the cloud weight band.
var ndvi = image.normalizedDifference(['B5', 'B4']).addBands(cloudWeight);
// Define an arbitrary region in a cloudy area.
var region = ee.Geometry.Rectangle(9.9069, 0.5981, 10.5, 0.9757);
// Use a mean reducer.
var reducer = ee.Reducer.mean();
// Compute the unweighted mean.
var unweighted = ndvi.select(['nd']).reduceRegion(reducer, region, 30);
// compute mean weighted by cloudiness.
var weighted = ndvi.reduceRegion(reducer.splitWeights(), region, 30);
// Observe the difference as a result of weighting by cloudiness.
print('unweighted:', unweighted);
print('weighted:', weighted);
Python の設定
Python API とインタラクティブな開発で geemap を使用する方法については、
Python 環境のページをご覧ください。
import ee
import geemap.core as geemap
Colab(Python)
# Load an input Landsat 8 image.
image = ee.Image('LANDSAT/LC08/C02/T1_TOA/LC08_186059_20130419')
# Compute cloud score and reverse it such that the highest
# weight (100) is for the least cloudy pixels.
cloud_weight = ee.Image(100).subtract(
ee.Algorithms.Landsat.simpleCloudScore(image).select(['cloud'])
)
# Compute NDVI and add the cloud weight band.
ndvi = image.normalizedDifference(['B5', 'B4']).addBands(cloud_weight)
# Define an arbitrary region in a cloudy area.
region = ee.Geometry.Rectangle(9.9069, 0.5981, 10.5, 0.9757)
# Use a mean reducer.
reducer = ee.Reducer.mean()
# Compute the unweighted mean.
unweighted = ndvi.select(['nd']).reduceRegion(reducer, region, 30)
# compute mean weighted by cloudiness.
weighted = ndvi.reduceRegion(reducer.splitWeights(), region, 30)
# Observe the difference as a result of weighting by cloudiness.
display('unweighted:', unweighted)
display('weighted:', weighted)
reduceRegion() を呼び出す前に、cloudWeight をバンドとして追加する必要があります。この結果は、曇りのピクセルの重みが低下した結果、推定平均 NDVI が高くなっていることを示しています。
特に記載のない限り、このページのコンテンツはクリエイティブ・コモンズの表示 4.0 ライセンスにより使用許諾されます。コードサンプルは Apache 2.0 ライセンスにより使用許諾されます。詳しくは、Google Developers サイトのポリシーをご覧ください。Java は Oracle および関連会社の登録商標です。
最終更新日 2025-07-25 UTC。
[null,null,["最終更新日 2025-07-25 UTC。"],[[["\u003cp\u003eBy default, reducers in Earth Engine weight pixels based on their mask values, which can affect results when using operations like \u003ccode\u003eclip()\u003c/code\u003e.\u003c/p\u003e\n"],["\u003cp\u003eThe \u003ccode\u003eunweighted()\u003c/code\u003e function forces all pixels in a region to have equal weight when applying a reducer.\u003c/p\u003e\n"],["\u003cp\u003eTo explicitly control pixel weights, use \u003ccode\u003esplitWeights()\u003c/code\u003e on the reducer and provide a separate weight band in the input image.\u003c/p\u003e\n"],["\u003cp\u003eUsing weighted reducers allows for more accurate analysis by adjusting the influence of specific pixels based on factors like cloud cover.\u003c/p\u003e\n"]]],["Reducers, by default, weight image inputs based on mask values, relevant for fractional pixels. The `unweighted()` method forces equal pixel weighting within a region. `splitWeights()` allows for explicit weighting, demonstrated by weighting a mean Normalized Difference Vegetation Index (NDVI) by cloud score, reducing cloudy pixel influence. The difference between using weighted, unweighted or splitweight methods is illustrated with examples of Landsat 8 imagery using `reduceRegion()`. Weights should be added as bands before using `reduceRegion()`.\n"],null,["# Weighted Reductions\n\nBy default, reducers applied to imagery weight the inputs according to the mask value.\nThis is relevant in the context of fractional pixels created through operations such as\n`clip()`. Adjust this behavior by calling `unweighted()` on the\nreducer. Using an unweighted reducer forces all pixels in the region to have the same\nweight. The following example illustrates how pixel weighting can affect the reducer\noutput:\n\n### Code Editor (JavaScript)\n\n```javascript\n// Load a Landsat 8 input image.\nvar image = ee.Image('LANDSAT/LC08/C02/T1/LC08_044034_20140318');\n\n// Create an arbitrary region.\nvar geometry = ee.Geometry.Rectangle(-122.496, 37.532, -121.554, 37.538);\n\n// Make an NDWI image. It will have one band named 'nd'.\nvar ndwi = image.normalizedDifference(['B3', 'B5']);\n\n// Compute the weighted mean of the NDWI image clipped to the region.\nvar weighted = ndwi.clip(geometry)\n .reduceRegion({\n reducer: ee.Reducer.mean(),\n geometry: geometry,\n scale: 30})\n .get('nd');\n\n// Compute the UN-weighted mean of the NDWI image clipped to the region.\nvar unweighted = ndwi.clip(geometry)\n .reduceRegion({\n reducer: ee.Reducer.mean().unweighted(),\n geometry: geometry,\n scale: 30})\n .get('nd');\n\n// Observe the difference between weighted and unweighted reductions.\nprint('weighted:', weighted);\nprint('unweighted', unweighted);\n```\nPython setup\n\nSee the [Python Environment](/earth-engine/guides/python_install) page for information on the Python API and using\n`geemap` for interactive development. \n\n```python\nimport ee\nimport geemap.core as geemap\n```\n\n### Colab (Python)\n\n```python\n# Load a Landsat 8 input image.\nimage = ee.Image('LANDSAT/LC08/C02/T1/LC08_044034_20140318')\n\n# Create an arbitrary region.\ngeometry = ee.Geometry.Rectangle(-122.496, 37.532, -121.554, 37.538)\n\n# Make an NDWI image. It will have one band named 'nd'.\nndwi = image.normalizedDifference(['B3', 'B5'])\n\n# Compute the weighted mean of the NDWI image clipped to the region.\nweighted = (\n ndwi.clip(geometry)\n .reduceRegion(reducer=ee.Reducer.mean(), geometry=geometry, scale=30)\n .get('nd')\n)\n\n# Compute the UN-weighted mean of the NDWI image clipped to the region.\nunweighted = (\n ndwi.clip(geometry)\n .reduceRegion(\n reducer=ee.Reducer.mean().unweighted(), geometry=geometry, scale=30\n )\n .get('nd')\n)\n\n# Observe the difference between weighted and unweighted reductions.\ndisplay('weighted:', weighted)\ndisplay('unweighted', unweighted)\n```\n\nThe difference in results is due to pixels at the edge of the region receiving a weight\nof one as a result of calling `unweighted()` on the reducer.\n\nIn order to obtain an explicitly weighted output, it is preferable to set the weights\nexplicitly with `splitWeights()` called on the reducer. A reducer modified by\n`splitWeights()` takes two inputs, where the second input is the weight. The\nfollowing example illustrates `splitWeights()` by computing the weighted mean\nNormalized Difference Vegetation Index (NDVI) in a region, with the weights given by\ncloud score (the cloudier, the lower the weight):\n\n### Code Editor (JavaScript)\n\n```javascript\n// Load an input Landsat 8 image.\nvar image = ee.Image('LANDSAT/LC08/C02/T1_TOA/LC08_186059_20130419');\n\n// Compute cloud score and reverse it such that the highest\n// weight (100) is for the least cloudy pixels.\nvar cloudWeight = ee.Image(100).subtract(\n ee.Algorithms.Landsat.simpleCloudScore(image).select(['cloud']));\n\n// Compute NDVI and add the cloud weight band.\nvar ndvi = image.normalizedDifference(['B5', 'B4']).addBands(cloudWeight);\n\n// Define an arbitrary region in a cloudy area.\nvar region = ee.Geometry.Rectangle(9.9069, 0.5981, 10.5, 0.9757);\n\n// Use a mean reducer.\nvar reducer = ee.Reducer.mean();\n\n// Compute the unweighted mean.\nvar unweighted = ndvi.select(['nd']).reduceRegion(reducer, region, 30);\n\n// compute mean weighted by cloudiness.\nvar weighted = ndvi.reduceRegion(reducer.splitWeights(), region, 30);\n\n// Observe the difference as a result of weighting by cloudiness.\nprint('unweighted:', unweighted);\nprint('weighted:', weighted);\n```\nPython setup\n\nSee the [Python Environment](/earth-engine/guides/python_install) page for information on the Python API and using\n`geemap` for interactive development. \n\n```python\nimport ee\nimport geemap.core as geemap\n```\n\n### Colab (Python)\n\n```python\n# Load an input Landsat 8 image.\nimage = ee.Image('LANDSAT/LC08/C02/T1_TOA/LC08_186059_20130419')\n\n# Compute cloud score and reverse it such that the highest\n# weight (100) is for the least cloudy pixels.\ncloud_weight = ee.Image(100).subtract(\n ee.Algorithms.Landsat.simpleCloudScore(image).select(['cloud'])\n)\n\n# Compute NDVI and add the cloud weight band.\nndvi = image.normalizedDifference(['B5', 'B4']).addBands(cloud_weight)\n\n# Define an arbitrary region in a cloudy area.\nregion = ee.Geometry.Rectangle(9.9069, 0.5981, 10.5, 0.9757)\n\n# Use a mean reducer.\nreducer = ee.Reducer.mean()\n\n# Compute the unweighted mean.\nunweighted = ndvi.select(['nd']).reduceRegion(reducer, region, 30)\n\n# compute mean weighted by cloudiness.\nweighted = ndvi.reduceRegion(reducer.splitWeights(), region, 30)\n\n# Observe the difference as a result of weighting by cloudiness.\ndisplay('unweighted:', unweighted)\ndisplay('weighted:', weighted)\n```\n\nObserve that `cloudWeight` needs to be added as a band prior to calling\n`reduceRegion()`. The result indicates that the estimated mean NDVI is\nhigher as a result of decreasing the weight of cloudy pixels."]]
