# I must have precision [closed]

I have gotten my android code well developed and again run into problemss with precision can someone help me get past this, please

Here is my code

``````// m1_els1_met = 310 and m1_els2_met = 320

static final double ELIP = 0.7854;
static final double mm_to_inch = 0.0393700787; //multiply

double m1_els1_met = new Double(m1_els1.getText().toString());
double m1_els1_eng = new Double(m1_els1_met) * mm_to_inch;
double m1_els2_met = new Double(m1_els2.getText().toString());
double m1_els2_eng = new Double(m1_els2_met) * mm_to_inch;

// elliptical area equals D1 x D2 x 0.7854

double eliptical_area_inches = (m1_els1_eng * m1_els2_eng) * ELIP;
String eliptical_area_inches_result = String.format("%.4f", eliptical_area_inches);
m1_sa_in.setText(eliptical_area_inches_result);
``````

I am expecting m1_sa_in to equal 121.8784 but I get 120.7 something instead. With precision my program is worthless.

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use java.math.BigDecimal –  zmf Nov 1 '11 at 18:45
This has nothing to do with precision. The result simply is `120.7xxxx`. –  Howard Nov 1 '11 at 18:48

## closed as too localized by EJP, Tim Post♦Nov 11 '11 at 6:17

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``````310 * 0.0393700787 = 12.204724397
320 * 0.0393700787 = 12.598425184

12.204... * 12.598... = 153.7603007207

153.7603007207 * 0.7854 = 120.76334018
``````
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you are so right, I had an error in an excel formula that I am using to validate my java code I am an idiot –  WmBurkert Nov 1 '11 at 19:59

You need to learn about the benefits and limitations of floating point before you decide that it can support the precision you desire.

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(310*.0393700787) * (320*.0393700787) * 0.7854 = 120.7633452802

(310/25.4) * (320/25.4) * 0.7854 = 120.76334536

120.7 something is the correct answer.

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Rather than using Math.PI/4, you are using ELIP which is only given to four significant figures, so you shouldn't be quoting a result to any more than three.

((((310 * 320) / 25.4) / 25.4) * pi) / 4 = 120.763063

``````System.out.println((310/25.4)*(320/25.4)*Math.PI/4);
> 120.76306313011793
``````

So getting 121 to three sig fig is fine, and if you want more precision, use the longer constants. When your inputs are know to better than sixteen significant figures (you have measured a small country to the accuracy of one atomic radius), then worry about moving to BigDecimal.

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Look at big decimal. That will handle the precision for you. Floating point libraries are dangerous if you really need precision.

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I'd say look at your problem first, and figure out whether you really need the precision BigDecimal offers. If you're working with natural measurements, you almost never do. Absolute precision only tends to matter when man-made numbers (like money) get involved. Using big decimals when you don't need to is almost as bad as not using them when you do. –  cHao Nov 1 '11 at 19:32
I almost rewrote the dand code, 75% of my validation was right on then all of a sudden I got to this problem and thought precision was my problem. For once my java was better than my excel validation formulas –  WmBurkert Nov 1 '11 at 20:02

Use the BigDecimal class. Doubles are subject to precision errors.

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Errors of like .0000001% or something are normal for doubles. Errors of like 1%, though, are indicative of bigger problems (like math or logic errors), problems that BigDecimal won't solve. –  cHao Nov 1 '11 at 19:16
It appears that your math above is off and that the answer is indeed about 120.7 something. What's more, a double is only accurate up to a certain decimal place. With numbers this small, you are risking a major loss of precision orders of magnitude larger than .00001%. –  James Nov 1 '11 at 19:18
A double uses...i think it's 52?...bits for the significand, regardless of whether the value is 1 or 10000000000. The rounding error (as related to the number) is about the same regardless of how big or small the number is. Rounding errors are actually smaller when the number is smaller. –  cHao Nov 1 '11 at 19:27
You're forgetting that the numbers must be converted to binary before the processor can operate on them. This is where the losses occur in the double primitive type. The larger the binary number (remember, binary has no concept of a decimal point), the harder it is for the number to be represented as binary on the processor registers. Getting mad and voting down my answer doesn't change that. –  James Nov 1 '11 at 19:35
All bases (including binary) have a concept of a "radix point". Just happens that a radix point in base 10 is called a decimal point. And the precision is the number of significant digits (in base 2, "bits"), and has very little to do with the actual size of the number. 1.1 might actually turn into 1.09999999999999 due to rounding error, but it certainly won't turn into 1.2. Likewise, 100.1 might become 100.0999999999999, but it won't turn into 100.2. You need to get into the billions+ before rounding errors are that significant, and at that point the difference is too small to matter. –  cHao Nov 1 '11 at 19:45