# Fast Hypotenuse Algorithm for Embedded Processor?

Is there a clever/efficient algorithm for determining the hypotenuse of an angle (i.e. `sqrt(a² + b²)`), using fixed point math on an embedded processor without hardware multiply?

• Can you avoid the `sqrt`? E.g. only compare vs `lenSquared` vs `len`? A lot's going to depend on your processor. Can you tell us what it is? Aug 17, 2010 at 20:01
• In this case, the sqrt is necessary. The application involves manipulating data from an accelerometer and running it through a non-linear filter. The processor in question has an 8-bit RISC instruction set, the Atmel ATTiny44A (datasheet: atmel.com/dyn/resources/prod_documents/doc8183.pdf).
– Tim
Aug 17, 2010 at 20:11
• Bets on PIC10-16 or tinyAVR. Aug 17, 2010 at 20:11
• By the way, anyone interested in embedded processing should consider joining the Electronics and Robotics stackexchange. Aug 17, 2010 at 20:46
• There are some serious terminology issues here. The hypotenuse is the line segment opposite the right angle of a right triangle. You want the length of the hypotenuse. Moreover, you may (or may not) actually want the inverse <trig function> rather than the Pythagorean expression. Aug 17, 2010 at 21:41

If the result doesn't have to be particularly accurate, you can get a crude approximation quite simply:

Take absolute values of `a` and `b`, and swap if necessary so that you have `a <= b`. Then:

``````h = ((sqrt(2) - 1) * a) + b
``````

To see intuitively how this works, consider the way that a shallow angled line is plotted on a pixel display (e.g. using Bresenham's algorithm). It looks something like this:

``````+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| | | | | | | | | | | | | | | | |*|*|*|    ^
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+    |
| | | | | | | | | | | | |*|*|*|*| | | |    |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+    |
| | | | | | | | |*|*|*|*| | | | | | | | a pixels
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+    |
| | | | |*|*|*|*| | | | | | | | | | | |    |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+    |
|*|*|*|*| | | | | | | | | | | | | | | |    v
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
<-------------- b pixels ----------->
``````

For each step in the `b` direction, the next pixel to be plotted is either immediately to the right, or one pixel up and to the right.

The ideal line from one end to the other can be approximated by the path which joins the centre of each pixel to the centre of the adjacent one. This is a series of `a` segments of length `sqrt(2)`, and `b-a` segments of length 1 (taking a pixel to be the unit of measurement). Hence the above formula.

This clearly gives an accurate answer for `a == 0` and `a == b`; but gives an over-estimate for values in between.

The error depends on the ratio `b/a`; the maximum error occurs when `b = (1 + sqrt(2)) * a` and turns out to be `2/sqrt(2+sqrt(2))`, or about 8.24% over the true value. That's not great, but if it's good enough for your application, this method has the advantage of being simple and fast. (The multiplication by a constant can be written as a sequence of shifts and adds.)

• That's quite a clever approximation.
– caf
Aug 18, 2010 at 2:16
• Nice; but you should probably mention to take the absolute value of both a and b as well. +1 for some brief error analysis Aug 18, 2010 at 14:16
• The formula above gives a octagonal profile, which works for me. To break it further and stick to integers (no floats!), taking sqr(2) as 0.414213562, bump up the decimal&round: 4142 and dividing it back down later (/10000) works quite fast! many times more without the float constant `h=4142*abs(a)/10000+abs(b)` Thanks! ** That ratio is awful close to 1:2, so using just bit shifting and mul+add I get a very good facsimile `h=(a>>1)+b` Jun 4, 2014 at 8:33
• Nice idea. The error can be up to 10%, though. (I'm getting an error of 19 for a length of 231, for example. The error can also be under 1% for some values, but it's generally 5-7%.) Aug 18, 2014 at 23:46
• @MatthewSlattery could you provide a reference to this method? I know it's been a while but I desperately need to cite this. Aug 8, 2015 at 13:59

For the record, here are a few more approximations, listed in roughly increasing order of complexity and accuracy. All these assume 0 ≤ a ≤ b.

• `h = b + 0.337 * a // max error ≈ 5.5 %`
• `h = max(b, 0.918 * (b + (a>>1))) // max error ≈ 2.6 %`
• `h = b + 0.428 * a * a / b // max error ≈ 1.04 %`

Edit: to answer Ecir Hana's question, here is how I derived these approximations.

First step. Approximating a function of two variables can be a complex problem. Thus I first transformed this into the problem of approximating a function of one variable. This can be done by choosing the longest side as a “scale” factor, as follows:

h = √(b2 + a2)
= b √(1 + (a/b)2)
= b f(a/b)    where f(x) = √(1+x2)

Adding the constraint 0 ≤ a ≤ b means we are only concerned with approximating f(x) in the interval [0, 1].

Below is the plot of f(x) in the relevant interval, together with the approximation given by Matthew Slattery (namely (√2−1)x + 1).

Second step. Next step is to stare at this plot, while asking yourself the question “how can I approximate this function cheaply?”. Since the curve looks roughly parabolic, my first idea was to use a quadratic function (third approximation). But since this is still relatively expensive, I also looked at linear and piecewise linear approximations. Here are my three solutions:

The numerical constants (0.337, 0.918 and 0.428) were initially free parameters. The particular values were chosen in order to minimize the maximum absolute error of the approximations. The minimization could certainly be done by some algorithm, but I just did it “by hand”, plotting the absolute error and tuning the constant until it is minimized. In practice this works quite fast. Writing the code to automate this would have taken longer.

Third step is to come back to the initial problem of approximating a function of two variables:

• h ≈ b (1 + 0.337 (a/b)) = b + 0.337 a
• h ≈ b max(1, 0.918 (1 + (a/b)/2)) = max(b, 0.918 (b + a/2))
• h ≈ b (1 + 0.428 (a/b)2) = b + 0.428 a2/b
• Please, can you explain how the constants/approximations were derived? May 25, 2017 at 15:11
• @EcirHana: See expanded answer. May 25, 2017 at 19:40
• Very interesting! Thanks a lot for the explanation! May 25, 2017 at 22:04

Consider using CORDIC methods. Dr. Dobb's has an article and associated library source here. Square-root, multiply and divide are dealt with at the end of the article.

• Note: I have used this library and found an error in the log() function. This is corrected by adding a `0x0LL` to the end of the `log_two_power_n_reversed[]` array initialiser. I have confirmed this correction with the author. Oct 20, 2010 at 9:19

One possibility looks like this:

``````#include <math.h>

/* Iterations   Accuracy
*  2          6.5 digits
*  3           20 digits
*  4           62 digits
* assuming a numeric type able to maintain that degree of accuracy in
* the individual operations.
*/
#define ITER 3

double dist(double P, double Q) {
/* A reasonably robust method of calculating `sqrt(P*P + Q*Q)'
*
* Transliterated from _More Programming Pearls, Confessions of a Coder_
* by Jon Bentley, pg. 156.
*/

double R;
int i;

P = fabs(P);
Q = fabs(Q);

if (P<Q) {
R = P;
P = Q;
Q = R;
}

/* The book has this as:
*  if P = 0.0 return Q; # in AWK
* However, this makes no sense to me - we've just insured that P>=Q, so
* P==0 only if Q==0;  OTOH, if Q==0, then distance == P...
*/
if ( Q == 0.0 )
return P;

for (i=0;i<ITER;i++) {
R = Q / P;
R = R * R;
R = R / (4.0 + R);
P = P + 2.0 * R * P;
Q = Q * R;
}
return P;
}
``````

This still does a couple of divides and four multiples per iteration, but you rarely need more than three iterations (and two is often adequate) per input. At least with most processors I've seen, that'll generally be faster than the `sqrt` would be on its own.

For the moment it's written for `double`s, but assuming you've implemented the basic operations, converting it to work with fixed point shouldn't be terribly difficult.

Some doubts have been raised by the comment about "reasonably robust". At least as originally written, this was basically a rather backhanded way of saying that "it may not be perfect, but it's still at least quite a bit better than a direct implementation of the Pythagorean theorem."

In particular, when you square each input, you need roughly twice as many bits to represent the squared result as you did to represent the input value. After you add (which needs only one extra bit) you take the square root, which gets you back to needing roughly the same number of bits as the inputs. Unless you have a type with substantially greater precision than the inputs, it's easy for this to produce really poor results.

This algorithm doesn't square either input directly. It is still possible for an intermediate result to underflow, but it's designed so that when it does so, the result still comes out as well as the format in use supports. Basically, the situation in which it happens is that you have an extremely acute triangle (e.g., something like 90 degrees, 0.000001 degrees, and 89.99999 degrees). If it's close enough to 90, 0, 90, we may not be able to represent the difference between the two longer sides, so it'll compute the hypotenuse as being the same length as the other long side.

By contrast, when the Pythagorean theorem fails, the result will often be a NaN (i.e., tells us nothing) or, depending on the floating point format in use, quite possibly something that looks like a reasonable answer, but is actually wildly incorrect.

• What does "reasonably robust" mean? Does that mean that it does not work in all cases!? Aug 17, 2010 at 20:37
• There's no way that math.h and a double type is going to fit on an ATTiny. You get 4k of program space, maximum, and both division and multiplication are going to be in software. However, this would work well for a processor with a hardware multiply (or divide) instruction. Aug 17, 2010 at 20:38
• @reemevnivek: yes, but trying to present it for an unknown fixed-point format is next to impossible. `<math.h>` is being used only for `fabs`, so its inclusion (by itself) would mean next to nothing (including a header normally only declares things; only what you use goes in the executable). Ultimately you're right though: as the final sentence makes clear, I certainly wouldn't expect to use this as-is on a micro-controller. Aug 17, 2010 at 20:53
• Agreed; I merely thought that "reasonably robust" without qualification or quantification was a bit weak as a comment, and would require analysis on the part of the user to determine the consequences of using this code. It may have meant that it would fail in non-deterministic ways rather than just for a deterministic range of inputs, or it may simply refer to its precision in all cases rather than its correctness in some cases. The comment alone would ring alarm bells for example if this were a safety-critical application. Aug 18, 2010 at 9:42
• @JerryCoffin wow, 10 years on, you ressurect this? I think editing the answer to quantify what you meant was what I was after - 10 years ago. Not for my own benefit; I could work that out for myself. Rather it was a suggestion to improve an already good answer, and remove any doubt that the statement might instill in any novice. Comments don't really suffice for that. Dec 29, 2020 at 23:22

You can start by reevaluating if you need the `sqrt` at all. Many times you are calculating the hypotenuse just to compare it to another value - if you square the value you're comparing against you can eliminate the square root altogether.

Unless you're doing this at >1kHz, multiply even on a MCU without hardware `MUL` isn't terrible. What's much worse is the `sqrt`. I would try to modify my application so it doesn't need to calculate it at all.

Standard libraries would probably be best if you actually need it, but you could look at using Newton's method as a possible alternative. It would require several multiply/divide cycles to perform, however.

### AVR resources

• You don't need to divide to approximate a square root. You can easily just use a binary-search type algorithm that only does one multiply per bit and no divides.
– Gabe
Aug 17, 2010 at 20:32

Maybe you could use some of Elm Chans Assembler Libraries and adapt the ihypot-function to your ATtiny. You would need to replace the MUL and maybe (i haven't checked) some other instructions.