Check results for 'npmv'

using R Under development (unstable) (2024-11-19 r87348 ucrt)
using platform: x86_64-w64-mingw32
R was compiled by gcc.exe (GCC) 13.3.0 GNU Fortran (GCC) 13.3.0
running under: Windows Server 2022 x64 (build 20348)
using session charset: UTF-8
checking for file 'npmv/DESCRIPTION' ... OK
checking extension type ... Package
this is package 'npmv' version '2.4.0'
checking package namespace information ... OK
checking package dependencies ... OK
checking if this is a source package ... OK
checking if there is a namespace ... OK
checking for hidden files and directories ... OK
checking for portable file names ... OK
checking whether package 'npmv' can be installed ... OK See the install log for details.
checking installed package size ... OK
checking package directory ... OK
checking DESCRIPTION meta-information ... OK
checking top-level files ... OK
checking for left-over files ... OK
checking index information ... OK
checking package subdirectories ... OK
checking code files for non-ASCII characters ... OK
checking R files for syntax errors ... OK
checking whether the package can be loaded ... [0s] OK
checking whether the package can be loaded with stated dependencies ... [0s] OK
checking whether the package can be unloaded cleanly ... [0s] OK
checking whether the namespace can be loaded with stated dependencies ... [0s] OK
checking whether the namespace can be unloaded cleanly ... [0s] OK
checking loading without being on the library search path ... [0s] OK
checking use of S3 registration ... OK
checking dependencies in R code ... OK
checking S3 generic/method consistency ... OK
checking replacement functions ... OK
checking foreign function calls ... OK
checking R code for possible problems ... [4s] OK
checking Rd files ... [1s] NOTE checkRd: (-1) nonpartest.Rd:69: Lost braces; missing escapes or markup? 69 | \[H=(1/(a-1))*sum_{i=1}^a n (Rbar_{i .}-Rbar_{..})(Rbar_{i.}-Rbar_{..})' \] | ^ checkRd: (-1) nonpartest.Rd:69: Lost braces; missing escapes or markup? 69 | \[H=(1/(a-1))*sum_{i=1}^a n (Rbar_{i .}-Rbar_{..})(Rbar_{i.}-Rbar_{..})' \] | ^ checkRd: (-1) nonpartest.Rd:69: Lost braces; missing escapes or markup? 69 | \[H=(1/(a-1))*sum_{i=1}^a n (Rbar_{i .}-Rbar_{..})(Rbar_{i.}-Rbar_{..})' \] | ^ checkRd: (-1) nonpartest.Rd:69: Lost braces; missing escapes or markup? 69 | \[H=(1/(a-1))*sum_{i=1}^a n (Rbar_{i .}-Rbar_{..})(Rbar_{i.}-Rbar_{..})' \] | ^ checkRd: (-1) nonpartest.Rd:69: Lost braces; missing escapes or markup? 69 | \[H=(1/(a-1))*sum_{i=1}^a n (Rbar_{i .}-Rbar_{..})(Rbar_{i.}-Rbar_{..})' \] | ^ checkRd: (-1) nonpartest.Rd:70: Lost braces; missing escapes or markup? 70 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) nonpartest.Rd:70: Lost braces; missing escapes or markup? 70 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) nonpartest.Rd:70: Lost braces; missing escapes or markup? 70 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) nonpartest.Rd:70: Lost braces; missing escapes or markup? 70 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) nonpartest.Rd:70: Lost braces; missing escapes or markup? 70 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) nonpartest.Rd:70: Lost braces; missing escapes or markup? 70 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) nonpartest.Rd:75: Lost braces; missing escapes or markup? 75 | \[fhat_1=(tr(G)^2/tr(G^2)) and fhat_2= (a^2)/((a-1)sum^a_{i=1}(1)/(n_i-1))* fhat_1 | ^ checkRd: (-1) nonpartest.Rd:78: Lost braces; missing escapes or markup? 78 | \[U=tr[(a-1)H((N-a)G)^{-1}]\] Using the McKeon approximation the distribution of U is approximated by a "stretched" F distribution with degrees freedom K and D where: | ^ checkRd: (-1) nonpartest.Rd:83: Lost braces; missing escapes or markup? 83 | \[V= tr\{(a-1)H[(a-1)H+(N-a)G]^{-1}\}\] | ^ checkRd: (-1) nonpartest.Rd:92: Lost braces; missing escapes or markup? 92 | \[F_lambda=[(1-lambda^{1/t})/(lambda^{1/t})](df_2/df_1)\] | ^ checkRd: (-1) nonpartest.Rd:92: Lost braces; missing escapes or markup? 92 | \[F_lambda=[(1-lambda^{1/t})/(lambda^{1/t})](df_2/df_1)\] | ^ checkRd: (-1) nonpartest.Rd:98: Lost braces 98 | \[p(a-1)=2 then t=1, else t=sqrt{ (p^2(a-1)^2-4)/(p^2+(a-1)^2-5) }\] | ^ checkRd: (-1) ssnonpartest.Rd:64: Lost braces; missing escapes or markup? 64 | \[H=(1/(a-1))*sum_{i=1}^a n (Rbar_{i .}-Rbar_{..})(Rbar_{i.}-Rbar_{..})' \] | ^ checkRd: (-1) ssnonpartest.Rd:64: Lost braces; missing escapes or markup? 64 | \[H=(1/(a-1))*sum_{i=1}^a n (Rbar_{i .}-Rbar_{..})(Rbar_{i.}-Rbar_{..})' \] | ^ checkRd: (-1) ssnonpartest.Rd:64: Lost braces; missing escapes or markup? 64 | \[H=(1/(a-1))*sum_{i=1}^a n (Rbar_{i .}-Rbar_{..})(Rbar_{i.}-Rbar_{..})' \] | ^ checkRd: (-1) ssnonpartest.Rd:64: Lost braces; missing escapes or markup? 64 | \[H=(1/(a-1))*sum_{i=1}^a n (Rbar_{i .}-Rbar_{..})(Rbar_{i.}-Rbar_{..})' \] | ^ checkRd: (-1) ssnonpartest.Rd:64: Lost braces; missing escapes or markup? 64 | \[H=(1/(a-1))*sum_{i=1}^a n (Rbar_{i .}-Rbar_{..})(Rbar_{i.}-Rbar_{..})' \] | ^ checkRd: (-1) ssnonpartest.Rd:65: Lost braces; missing escapes or markup? 65 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) ssnonpartest.Rd:65: Lost braces; missing escapes or markup? 65 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) ssnonpartest.Rd:65: Lost braces; missing escapes or markup? 65 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) ssnonpartest.Rd:65: Lost braces; missing escapes or markup? 65 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) ssnonpartest.Rd:65: Lost braces; missing escapes or markup? 65 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) ssnonpartest.Rd:65: Lost braces; missing escapes or markup? 65 | \[G=(1/(N-1))*sum_{i=1}^a sum_{j=1}^n(R_{ij}-Rbar_{i.})(R_{ij}-Rbar_{i.})'\] | ^ checkRd: (-1) ssnonpartest.Rd:70: Lost braces; missing escapes or markup? 70 | \[fhat_1=(tr(G)^2/tr(G^2)) and fhat_2= (a^2)/((a-1)sum^a_{i=1}(1)/(n_i-1))* fhat_1 | ^ checkRd: (-1) ssnonpartest.Rd:73: Lost braces; missing escapes or markup? 73 | \[U=tr[(a-1)H((N-a)G)^{-1}]\] Using the McKeon approximation the distribution of U is approximated by a "stretched" F distribution with degrees freedom K and D where: | ^ checkRd: (-1) ssnonpartest.Rd:78: Lost braces; missing escapes or markup? 78 | \[V= tr\{(a-1)H[(a-1)H+(N-a)G]^{-1}\}\] | ^ checkRd: (-1) ssnonpartest.Rd:87: Lost braces; missing escapes or markup? 87 | \[F_lambda=[(1-lambda^{1/t})/(lambda^{1/t})](df_2/df_1)\] | ^ checkRd: (-1) ssnonpartest.Rd:87: Lost braces; missing escapes or markup? 87 | \[F_lambda=[(1-lambda^{1/t})/(lambda^{1/t})](df_2/df_1)\] | ^ checkRd: (-1) ssnonpartest.Rd:93: Lost braces 93 | \[p(a-1)=2 then t=1, else t=sqrt{ (p^2(a-1)^2-4)/(p^2+(a-1)^2-5) }\] | ^
checking Rd metadata ... OK
checking Rd cross-references ... OK
checking for missing documentation entries ... OK
checking for code/documentation mismatches ... OK
checking Rd \usage sections ... OK
checking Rd contents ... OK
checking for unstated dependencies in examples ... OK
checking contents of 'data' directory ... OK
checking data for non-ASCII characters ... [0s] OK
checking data for ASCII and uncompressed saves ... OK
checking examples ... [6s] OK
checking PDF version of manual ... [21s] OK
checking HTML version of manual ... [1s] OK
DONE

Status: 1 NOTE