---
layout: default
title: Cholesky Decomposition
---
# Cholesky Decomposition
## What it computes
A factorization of a symmetric positive-definite matrix A into:
```
A = L · Lᵀ
```
where **L** is lower triangular with positive diagonal entries. It is the "square root" of
a matrix in the sense that multiplying L by its own transpose recovers A.
## Intuition
LU decomposition works for any invertible square matrix, but it doesn't exploit symmetry.
If you know A is symmetric and positive-definite, you can do roughly half the work: instead
of finding two different triangular matrices L and U, you find one (L) and observe that U
is simply Lᵀ.
The positive-definite condition (all eigenvalues positive) guarantees that the square root
exists and that all diagonal entries of L are real and positive — which is what makes the
algorithm work without pivoting.
## What "symmetric positive-definite" means
- **Symmetric:** Aᵢⱼ = Aⱼᵢ for all i, j (the matrix equals its own transpose).
- **Positive-definite:** for every non-zero vector x, xᵀAx > 0. Intuitively, A doesn't
flip any vector to point in an opposite direction.
Common sources: covariance matrices in statistics, stiffness matrices in structural
engineering, kernel matrices in machine learning.
## Method
Compute L column by column. For column j:
```
Lⱼⱼ = √(Aⱼⱼ − Σ Lⱼₖ²) (k from 1 to j−1)
Lᵢⱼ = (Aᵢⱼ − Σ LᵢₖLⱼₖ) / Lⱼⱼ (k from 1 to j−1, for i > j)
```
If at any point the expression inside the square root is negative or zero, the matrix is
not positive-definite and the decomposition does not exist.
**Example:**
```
| 2 3 6 | | 1 1 √3 |
```
Verify: L · Lᵀ = A.
## Computational cost
O(n³/3) — approximately half the cost of LU decomposition for the same matrix size,
because the symmetry means only the lower triangle needs to be computed.
## When to use it
- Solving Ax = b when A is symmetric positive-definite — the most efficient general method
in that case.
- Sampling from multivariate normal distributions (used in statistics and Monte Carlo
methods).
- As a fast check for positive-definiteness: if Cholesky succeeds, the matrix is positive-
definite; if it fails (negative under the square root), it is not.
## Limitations
- Only applicable to symmetric positive-definite matrices — will fail or produce incorrect
results otherwise.
- Requires a square root operation at each diagonal step.
- Does not need pivoting (unlike LU), which simplifies the implementation but also means
there is no fallback if the positive-definite condition is violated.