Supported features
Raw input data requirements
- Only numeric input is supported. That is, data must be either integer or real numbers, but not characters. The only exemption is genomic data.
- 64 bit integers are used to store integer data. That is, integer data may range from -9.223372e+18 to +9.223372e+18.
- All input data are renumbered automatically if required by the job and respective cross-reference files will be provided if necessary
- Files containing human readable data must be in comma-separated-value(csv) format
- Pedigree files must be complete. That is, all individual occurring as parents must occur as individuals. All individual ids which occur in the data file must occur in the pedigree.
- Genomic marker data must be imputed to common density across all genotypes and must contain no missing marker.
Supported operations
Currently lmt support the following operations on linear mixed models:
- Solving for BLUP and BLUE solutions conditional on supplied variances for random and fixed factor, respectively;
- Gibbs sampling of variance components in single pass and blocked mode;
- MC-EM-REML estimation of variance components
- Sampling (block)diagonal elements of the inverse of the mixed model coefficient matrix
- Solving for (block)diagonal elements of the inverse of the mixed model coefficient matrix
Supported factors and variables
lmt supports
- fixed
- random factors
- classification variables
- continuous co-variables, which can be nested. For continuous co-variables lmt support user-defined polynomials and hard coded Legendre polynomials up to order 6.
- genetic group co-variables
All classification and co-variables can be associated to a fixed or random factor.
Supported variance structures
For random factor lmt supports variance structures of
- structure $$\Gamma\otimes\Sigma$$, where $$\Sigma$$ is an dense symmetric positive definite matrix, and
- $$\Theta_L(\Gamma\otimes I_{\Sigma})\Theta_L^{'}$$, where $$\Theta$$ is symmetric positive definite block-diagonal matrix of $$n$$ symmetric positive definite martices $$\Sigma_i, i=1,..,n$$, $$\Theta_L$$ is the lower Cholesky factor of $$\Theta$$ and $$I_{\Sigma}$$ is an identity matrix of dimension $$\Sigma_i$$.
When solving linear mixed models $$\Sigma$$ and $$\Gamma$$ are user determined constants, whereas when estimating variances $$\Gamma$$ is a user determined constant and $$\Sigma$$ is a function of the data.
Supported type for $$\Gamma$$ are
- an identity matrix
- an arbitrary positive definite diagonal matrix
- a pedigree-based numerator relationship matrix $$A$$ which may contain meta-founders
- a pedigree- and genotype-based relationship matrix $$H$$ which may contain meta-founders
- genetic groups absorbed into $$A$$ or $$H$$
- a user-defined(u.d.) symmetric, positive definite matrix of which inverse is supplied
- as a sparse upper-triangular matrix stored in csr format
- as a dense matrix
- a co-variance matrix of a selected auto-regressive process
Further lmt supports special variance structures which are not covered by the above description
- SNP-BLUP variance for the model of Liu and Goddard 2014 with the option to model marker co-variances as above.
Supported linear mixed model solvers
lmt supports
- a direct solver requiring to explicitly build the linear mixed model equations left-hand-side coefficient matrix($$C$$)
- an iteration-on-data pre-conditioned gradient solver which does not require $$C$$
- direct use of genomic marker data
- building of genomic relationship matrices($$G$$) from supplied genomic data
- uploading of a u.d. $$G$$
- adjustment of $$G$$ to $$A_{gg}$$ in ssGBLUP and ssSNPBLUP
- solving ssGBLUP models
- Variance component estimation for ssGBLUP models
- solving ssGTBLUP models
- solving ssSNPBLUP models
- calculation of true H matrix diagonal elements for ssGBLUP models
- all Single-Step models can be run from "bottom-up", that is the user supplies the genotypes and all necessary ingredients(e.g. $$G$$) are built on the fly.
Supported pedigree types
- ordinary pedigrees
- probabilistic pedigrees with an unlimited number of parent pairs per individual
- genetic group pedigrees
- meta-founder pedigrees
- ignoring of inbreeding
- iterative derivation of inbreeding coefficients
- meta-founders can be modeled for all $$\Gamma$$ which contain $$A$$(.e.g. $$A$$, $$H$$ for ssGBLUP, ssGTBLUP and ssSNPBLUP)
- genetic groups can be modeled as an extra factor or can be absorbed into all $$\Gamma$$ which contain $$A$$