Implementation:Pyro ppl Pyro MaternKernel
| Property | Value |
|---|---|
| Module | pyro.ops.ssm_gp
|
| Source | pyro/ops/ssm_gp.py |
| Lines | 169 |
| Classes | MaternKernel
|
| Dependencies | torch, pyro.nn (PyroModule, PyroParam)
|
Overview
This module provides the MaternKernel class, which represents univariate Gaussian Processes (GPs) with Matern kernels as state space models (SSMs). This reformulation enables O(T) inference for GPs (instead of O(T^3) with standard GP methods) by leveraging the equivalence between Matern-kernel GPs and linear stochastic differential equations.
The class supports Matern kernels of order 0.5, 1.5, and 2.5, with corresponding state dimensions of 1, 2, and 3. The state space formulation follows Hartikainen & Sarkka (2010) and Solin (2016), computing:
- Transition matrices: How the GP latent state evolves over a time interval.
- Stationary covariance: The long-run covariance of the state.
- Process covariance: The noise covariance for a given time step.
Code Reference
Class: MaternKernel (PyroModule)
Constructor parameters:
nu(float): Matern kernel order (0.5, 1.5, or 2.5).num_gps(int): Number of independent GPs.length_scale_init(Tensor): Initial length scales, shape(num_gps,).kernel_scale_init(Tensor): Initial kernel scales, shape(num_gps,).
Learnable parameters:
length_scale: Positive constrained, shape(num_gps,).kernel_scale: Positive constrained, shape(num_gps,).
Methods:
transition_matrix(dt): Computes the exponentiated transition matrixA(dt)with layout(num_gps, state_dim, state_dim). This matrix multiplies states from the right.nu=0.5:exp(-dt / rho)(scalar)nu=1.5: 2x2 matrix involvingexp(-sqrt(3) * dt / rho)nu=2.5: 3x3 matrix involvingexp(-sqrt(5) * dt / rho)
stationary_covariance(): Computes the stationary covariance matrixP_infof shape(num_gps, state_dim, state_dim).
process_covariance(A): Given transition matrixA, computes process covarianceQ = P_inf - A.T @ P_inf @ A.
transition_matrix_and_covariance(dt): Convenience method returning both the transition matrix and process covariance for a time intervaldt.
I/O Contract
| Method | Input | Output |
|---|---|---|
__init__ |
nu: float, num_gps: int, optional init tensors |
MaternKernel (PyroModule)
|
transition_matrix(dt) |
dt: float (time interval) |
Tensor(num_gps, state_dim, state_dim)
|
stationary_covariance() |
(none) | Tensor(num_gps, state_dim, state_dim)
|
process_covariance(A) |
A: Tensor(..., state_dim, state_dim) |
Tensor(num_gps, state_dim, state_dim)
|
transition_matrix_and_covariance(dt) |
dt: float |
Tuple of two Tensor(num_gps, state_dim, state_dim)
|
Usage Examples
import torch
from pyro.ops.ssm_gp import MaternKernel
# Create a Matern-3/2 kernel for 2 independent GPs
kernel = MaternKernel(
nu=1.5,
num_gps=2,
length_scale_init=torch.tensor([1.0, 2.0]),
kernel_scale_init=torch.tensor([1.0, 0.5]),
)
# Compute transition matrix for dt=0.1
dt = 0.1
A = kernel.transition_matrix(dt)
print(A.shape) # torch.Size([2, 2, 2])
# Get both transition and process covariance
A, Q = kernel.transition_matrix_and_covariance(dt)
# Get stationary covariance
P_inf = kernel.stationary_covariance()
print(P_inf.shape) # torch.Size([2, 2, 2])
Related Pages
- Pyro_ppl_Pyro_Gaussian -- Gaussian operations used for Kalman filtering with SSM-GPs