This is machine translation

Translated by Microsoft
Mouseover text to see original. Click the button below to return to the English verison of the page.

Note: This page has been translated by MathWorks. Please click here
To view all translated materals including this page, select Japan from the country navigator on the bottom of this page.

Compute Sine and Cosine Using CORDIC Rotation Kernel

This example shows how to compute sine and cosine using a CORDIC rotation kernel in MATLAB®. CORDIC-based algorithms are critical to many embedded applications, including motor controls, navigation, signal processing, and wireless communications.


CORDIC is an acronym for COordinate Rotation DIgital Computer. The Givens rotation-based CORDIC algorithm (see [1,2]) is one of the most hardware efficient algorithms because it only requires iterative shift-add operations. The CORDIC algorithm eliminates the need for explicit multipliers, and is suitable for calculating a variety of functions, such as sine, cosine, arcsine, arccosine, arctangent, vector magnitude, divide, square root, hyperbolic and logarithmic functions.

The fixed-point CORDIC algorithm requires the following operations:

  • 1 table lookup per iteration

  • 2 shifts per iteration

  • 3 additions per iteration

CORDIC Kernel Algorithm Using the Rotation Computation Mode

You can use a CORDIC rotation computing mode algorithm to calculate sine and cosine simultaneously, compute polar-to-cartesian conversions, and for other operations. In the rotation mode, the vector magnitude and an angle of rotation are known and the coordinate (X-Y) components are computed after rotation.

The CORDIC rotation mode algorithm begins by initializing an angle accumulator with the desired rotation angle. Next, the rotation decision at each CORDIC iteration is done in a way that decreases the magnitude of the residual angle accumulator. The rotation decision is based on the sign of the residual angle in the angle accumulator after each iteration.

In rotation mode, the CORDIC equations are:

$$ z_{i+1} = z_{i} - d_{i}*\mbox{atan}(2^{-i}) $$

$$ x_{i+1} = x_{i} - y_{i}*d_{i}*2^{-i} $$

$$ y_{i+1} = y_{i} + x_{i}*d_{i}*2^{-i} $$

where $$  d_{i} = -1 $$ if $$ z_{i} < 0 $$, and $$ +1  $$ otherwise;

$$ i = 0, 1, ..., N-1 $$, and $$ N $$ is the total number of iterations.

This provides the following result as $$ N $$ approaches $$ +\infty $$:

$$ z_{N} = 0 $$

$$ x_{N} = A_{N}(x_{0}\cos{z_{0}} - y_{0}\sin{z_{0}}) $$

$$ y_{N} = A_{N}(y_{0}\cos{z_{0}} + x_{0}\sin{z_{0}}) $$


$$ A_{N} = \prod_{i=0}^{N-1}{\sqrt{1+2^{-2i}}} $$.

Typically $$ N $$ is chosen to be a large-enough constant value. Thus, $$ A_{N} $$ may be pre-computed.

In rotation mode, the CORDIC algorithm is limited to rotation angles between $$ -\pi/2 $$ and $$ \pi/2 $$. To support angles outside of that range, quadrant correction is often used.

Efficient MATLAB Implementation of a CORDIC Rotation Kernel Algorithm

A MATLAB code implementation example of the CORDIC Rotation Kernel algorithm follows (for the case of scalar x, y, and z). This same code can be used for both fixed-point and floating-point operation.

CORDIC Rotation Kernel

function [x, y, z] = cordic_rotation_kernel(x, y, z, inpLUT, n)
% Perform CORDIC rotation kernel algorithm for N iterations.
xtmp = x;
ytmp = y;
for idx = 1:n
    if z < 0
        z(:) = accumpos(z, inpLUT(idx));
        x(:) = accumpos(x, ytmp);
        y(:) = accumneg(y, xtmp);
        z(:) = accumneg(z, inpLUT(idx));
        x(:) = accumneg(x, ytmp);
        y(:) = accumpos(y, xtmp);
    xtmp = bitsra(x, idx); % bit-shift-right for multiply by 2^(-idx)
    ytmp = bitsra(y, idx); % bit-shift-right for multiply by 2^(-idx)

CORDIC-Based Sine and Cosine Computation Using Normalized Inputs

Sine and Cosine Computation Using the CORDIC Rotation Kernel

The judicious choice of initial values allows the CORDIC kernel rotation mode algorithm to directly compute both sine and cosine simultaneously.

First, the following initialization steps are performed:

  • The angle input look-up table inpLUT is set to atan(2 .^ -(0:N-1)).

  • $$ z_{0} $$ is set to the $$ \theta $$ input argument value.

  • $$ x_{0} $$ is set to $$ 1 / A_{N} $$.

  • $$ y_{0} $$ is set to zero.

After $$ N $$ iterations, these initial values lead to the following outputs as $$ N $$ approaches $$ +\infty $$:

  • $$ x_{N} \approx cos(\theta) $$

  • $$ y_{N} \approx sin(\theta) $$

Other rotation-kernel-based function approximations are possible via pre- and post-processing and using other initial conditions (see [1,2]).

The CORDIC algorithm is usually run through a specified (constant) number of iterations since ending the CORDIC iterations early would break pipelined code, and the CORDIC gain $$ A_{n} $$ would not be constant because $$ n $$ would vary.

For very large values of $$ n $$, the CORDIC algorithm is guaranteed to converge, but not always monotonically. You can typically achieve greater accuracy by increasing the total number of iterations.


Suppose that you have a rotation angle sensor (e.g. in a servo motor) that uses formatted integer values to represent measured angles of rotation. Also suppose that you have a 16-bit integer arithmetic unit that can perform add, subtract, shift, and memory operations. With such a device, you could implement the CORDIC rotation kernel to efficiently compute cosine and sine (equivalently, cartesian X and Y coordinates) from the sensor angle values, without the use of multiplies or large lookup tables.

sumWL  = 16; % CORDIC sum word length
thNorm = -1.0:(2^-8):1.0; % Normalized [-1.0, 1.0] angle values
theta  = fi(thNorm, 1, sumWL); % Fixed-point angle values (best precision)

z_NT   = numerictype(theta);             % Data type for Z
xyNT   = numerictype(1, sumWL, sumWL-2); % Data type for X-Y
x_out  = fi(zeros(size(theta)), xyNT);   % X array pre-allocation
y_out  = fi(zeros(size(theta)), xyNT);   % Y array pre-allocation
z_out  = fi(zeros(size(theta)), z_NT);   % Z array pre-allocation

niters = 13; % Number of CORDIC iterations
inpLUT = fi(atan(2 .^ (-((0:(niters-1))'))) .* (2/pi), z_NT); % Normalized
AnGain = prod(sqrt(1+2.^(-2*(0:(niters-1))))); % CORDIC gain
inv_An = 1 / AnGain; % 1/A_n inverse of CORDIC gain

for idx = 1:length(theta)
    % CORDIC rotation kernel iterations
    [x_out(idx), y_out(idx), z_out(idx)] = ...
            fi(inv_An, xyNT), fi(0, xyNT), theta(idx), inpLUT, niters);

% Plot the CORDIC-approximated sine and cosine values
plot(thNorm, x_out);
axis([-1 1 -1 1]);
title('Normalized X Values from CORDIC Rotation Kernel Iterations');
thetaRadians = pi/2 .* thNorm; % real-world range [-pi/2 pi/2] angle values
plot(thNorm, cos(thetaRadians) - double(x_out));
title('Error between MATLAB COS Reference Values and X Values');
plot(thNorm, y_out);
axis([-1 1 -1 1]);
title('Normalized Y Values from CORDIC Rotation Kernel Iterations');
plot(thNorm, sin(thetaRadians) - double(y_out));
title('Error between MATLAB SIN Reference Values and Y Values');


  1. Jack E. Volder, The CORDIC Trigonometric Computing Technique, IRE Transactions on Electronic Computers, Volume EC-8, September 1959, pp330-334.

  2. Ray Andraka, A survey of CORDIC algorithm for FPGA based computers, Proceedings of the 1998 ACM/SIGDA sixth international symposium on Field programmable gate arrays, Feb. 22-24, 1998, pp191-200

Was this topic helpful?