projnormal.formulas.projected_normal
Formulas for the projected normal distribution, given by \(y=x/\|x\|\).
- empirical_moments(mean_x, covariance_x, n_samples)
Compute the mean, covariance and second moment of the variable \(y = x/\sqrt{x^T x}\), where \(x \sim \mathcal{N}(\mu_x, \Sigma_x)\), by sampling from the distribution. The variable \(y\) has a general projected normal distribution.
- Parameters:
mean_x (
torch.Tensor) – Mean of x. Shape is(n_dim,).covariance_x (
torch.Tensor) – Covariance of x. Shape is(n_dim, n_dim).n_samples (
int) – Number of samples.
- Returns:
Dictionary with the keys
mean,covariance, andsecond_moment, containing the empirical moments of the projected normal distribution.- Return type:
dict
- log_pdf(mean_x, covariance_x, y)
Compute the log-pdf at points y for the distribution of the variable \(y = x/\sqrt{x^T x}\), where \(x \sim \mathcal{N}(\mu_x, \Sigma_x)\). (\(y\) has a projected normal distribution.).
- Parameters:
mean_x (
torch.Tensor) – Mean of x. Shape is(n_dim,).covariance_x (
torch.Tensor) – Covariance of x. Shape is(n_dim, n_dim).y (
torch.Tensor) – Points where to evaluate the PDF. Shape is(n_points, n_dim).
- Returns:
Log-PDF evaluated at each y. Shape is
(n_points,).- Return type:
torch.Tensor
- mean(mean_x, covariance_x)
Compute the mean of \(y = x/\sqrt{x^T x}\), where \(x \sim \mathcal{N}(\mu_x, \Sigma_x)\) via Taylor approximation. (\(y\) has a projected normal distribution.).
- Parameters:
mean_x (
torch.Tensor) – Mean of x. Shape is(n_dim,).covariance_x (
torch.Tensor) – Covariance of x. Shape is(n_dim, n_dim).
- Returns:
Expected value for the projected normal. Shape is
(n_dim,).- Return type:
torch.Tensor
- pdf(mean_x, covariance_x, y)
Compute the pdf at points y for the distribution of the variable \(y = x/\sqrt{x^T x}\), where \(x \sim \mathcal{N}(\mu_x, \Sigma_x)\). (\(y\) has a projected normal distribution.).
- Parameters:
mean_x (
torch.Tensor) – Mean of x. Shape is(n_dim,).covariance_x (
torch.Tensor) – Covariance of x. Shape is(n_dim, n_dim).y (
torch.Tensor) – Points where to evaluate the PDF. Shape is(n_points, n_dim).
- Returns:
PDF evaluated at each y. Shape is
(n_points,).- Return type:
torch.Tensor
- sample(mean_x, covariance_x, n_samples)
Sample the variable \(y = x/\sqrt{x^T x}\) where \(x \sim \mathcal{N}(\mu_x, \Sigma_x)\).
- Parameters:
mean_x (
torch.Tensor) – Mean of x. Shape is(n_dim,).covariance_x (
torch.Tensor) – Covariance of x. Shape is(n_dim, n_dim).n_samples (
int) – Number of samples.
- Returns:
Samples from the projected normal. Shape is
(n_samples, n_dim).- Return type:
torch.Tensor
- second_moment(mean_x, covariance_x)
Compute the second moment matrix of \(y = x/\sqrt{x^T x}\), where \(x \sim \mathcal{N}(\mu_x, \Sigma_x)\) via Taylor approximation. (\(y\) has a projected normal distribution.).
- Parameters:
mean_x (
torch.Tensor) – Mean of x. Shape is(n_dim,).covariance_x (
torch.Tensor) – Covariance of x. Shape is(n_dim, n_dim).
- Returns:
Second moment matrix of \(y\). Shape is
(n_dim, n_dim).- Return type:
torch.Tensor
Modules
Approximation to the moments of the general projected normal distribution. |
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Probability density function (PDF) for the general projected normal distribution. |
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Sampling functions for the general projected normal distribution. |