# algorithm to round to the next order of magnitude in R

I apologize if the title is not clear, but I couldn't explain it succinctly.

Given a vector of concentrations, I would like to round the maximum value to the next order of magnitude (i.e., 345 to 1000). Also, I would like to round the minimum value to the lower order of magnitude (i.e., 3.2 to 1). These concentrations may also be below 1 so for example 0.034 would need to be rounded to 0.01.

Any ideas?

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That's not rounding, but something else. You can round 32 to 30 and consequently 30 to 0, but not to 10 or 1. –  user unknown Oct 26 '11 at 18:19

I'm not sure about R, but this is a simple process to describe algorithmically.

Take the base 10 logarithm of the number, and apply a ceiling or floor to the result. Raise 10 to that power. Done.

You need a special case for 0 because you can't take a logarithm of 0.

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Thanks Mark! Exactly what I needed. –  aule Oct 26 '11 at 18:35

Here's a simple function that does what you're after:

``````log10_ceiling <- function(x) {
10^(ceiling(log10(x)))
}

log10_ceiling(c(345, 3.2, 0.034))
# [1] 1000.0   10.0    0.1
``````
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Nice Josh. Thanks! –  aule Oct 26 '11 at 18:36

Hadley's `plyr` package has an extremely flexible function called `round_any` which does this elegantly. Here is how you would call the function

``````round_any(x, accuracy, f = round)
``````

In your case, `x = 345`, `accuracy = 1000` and you want `f = ceiling`. So calling

``````round_any(x = 345, accuracy = 1000, f = ceiling)
``````

would do the job

EDIT. Just saw that you wanted the `maximum` to be rounded up to `ceiling` and the minimum values rounded down to `floor`. change the `f` in the function call to achieve this.

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Thanks for the info Ramnath! I'll check it out. –  aule Oct 26 '11 at 19:55

The accepted answer by Mark Ransom is mostly correct. Having implemented this in Java I have found some more areas that need to be addressed:

• Negative numbers need to be handled specially if you want -375 to yield -1000
• Ceiling for positive log values, floor + 1 for negative log values (the plus one is important if you want 0.456 to yield 1).

Here is my implementation in Java with passing unit tests

``````static double roundUpToNearestMagnitude(double n) {
if (n == 0d) return 1d;
boolean negative = n < 0;
double log = Math.log10(Math.abs(n));
double decimalPlaces = ((log > 0)) ? (Math.ceil(log)) : (Math.floor(log) + 1);
double rounded = Math.pow(10, decimalPlaces);
return negative ? -rounded : rounded;
}

@Test public void roundUpToNearestMagnitudeFifty() {
Assert.assertEquals(100d, roundUpToNearestMagnitude(50d), 0.000001);
}

@Test public void roundUpToNearestMagnitudeFive() {
Assert.assertEquals(10d, roundUpToNearestMagnitude(5d), 0.000001);
}

@Test public void roundUpToNearestMagnitudeZeroPointFive() {
Assert.assertEquals(1d, roundUpToNearestMagnitude(0.5d), 0.000001);
}

@Test public void roundUpToNearestMagnitudeZeroPointZeroFive() {
Assert.assertEquals(.1d, roundUpToNearestMagnitude(0.05d), 0.000001);
}

@Test public void roundUpToNearestMagnitudeZeroPointZeroZeroFive() {
Assert.assertEquals(.01d, roundUpToNearestMagnitude(0.005d), 0.000001);
}

@Test public void roundUpToNearestMagnitudeNegativeFifty() {
Assert.assertEquals(-100d, roundUpToNearestMagnitude(-50d), 0.000001);
}

@Test public void roundUpToNearestMagnitudeNegativeFive() {
Assert.assertEquals(-10d, roundUpToNearestMagnitude(-5d), 0.000001);
}

@Test public void roundUpToNearestMagnitudeNegativeZeroPointFive() {
Assert.assertEquals(-1d, roundUpToNearestMagnitude(-0.5d), 0.000001);
}

@Test public void roundUpToNearestMagnitudeNegativeZeroPointZeroFive() {
Assert.assertEquals(-.1d, roundUpToNearestMagnitude(-0.05d), 0.000001);
}

@Test public void roundUpToNearestMagnitudeNegativeZeroPointZeroZeroFive() {
Assert.assertEquals(-.01d, roundUpToNearestMagnitude(-0.005d), 0.000001);
}

@Test public void roundUpToNearestMagnitudeZero() {
Assert.assertEquals(1, roundUpToNearestMagnitude(0d), 0.000001);
}
``````
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