On an element-wise basis, computes the arccosine in radians of the input.
| Usage | Returns | Array.acos() | Array |
| Argument | Type | Details | this: input | Array | The input array. |
Examples
Code Editor (JavaScript)
print(ee.Array([-1]).acos()); // [π]
print(ee.Array([0]).acos()); // [π/2]
print(ee.Array([1]).acos()); // [0]
var start = -1;
var end = 1;
var points = ee.Array(ee.List.sequence(start, end, null, 50));
var values = points.acos();
// Plot acos() defined above.
var chart = ui.Chart.array.values(values, 0, points)
.setOptions({
viewWindow: {min: start, max: end},
hAxis: {
title: 'x',
viewWindowMode: 'maximized',
ticks: [
{v: start, f: start},
{v: 0, f: 0},
{v: end, f: end}]
},
vAxis: {
title: 'acos(x)',
ticks: [
{v: 0, f: 0},
{v: Math.PI / 2, f: 'π/2'},
{v: Math.PI, f: 'π'}]
},
lineWidth: 1,
pointSize: 0,
});
print(chart);
Python setup
See the
Python Environment page for information on the Python API and using
geemap for interactive development.
import ee
import geemap.core as geemap
Colab (Python)
import math
import altair as alt
import pandas as pd
display(ee.Array([-1]).acos()) # [π]
display(ee.Array([0]).acos()) # [π/2]
display(ee.Array([1]).acos()) # [0]
start = -1
end = 1
points = ee.Array(ee.List.sequence(start, end, None, 50))
values = points.acos()
df = pd.DataFrame({'x': points.getInfo(), 'acos(x)': values.getInfo()})
# Plot acos() defined above.
alt.Chart(df).mark_line().encode(
x=alt.X('x', axis=alt.Axis(values=[start, 0, end])),
y=alt.Y('acos(x)', axis=alt.Axis(values=[0, math.pi / 2, math.pi]))
)