The PHREG Procedure
- Overview
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Getting Started
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SyntaxPROC PHREG StatementASSESS StatementBASELINE StatementBAYES StatementBY StatementCLASS StatementCONTRAST StatementEFFECT StatementESTIMATE StatementFREQ StatementHAZARDRATIO StatementID StatementLSMEANS StatementLSMESTIMATE StatementMODEL StatementOUTPUT StatementProgramming StatementsRANDOM StatementSTRATA StatementSLICE StatementSTORE StatementTEST StatementWEIGHT Statement
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DetailsFailure Time DistributionTime and CLASS Variables UsagePartial Likelihood Function for the Cox ModelCounting Process Style of InputLeft-Truncation of Failure TimesThe Multiplicative Hazards ModelProportional Rates/Means Models for Recurrent EventsThe Frailty ModelProportional Subdistribution Hazards Model for Competing-Risks DataHazard RatiosNewton-Raphson MethodFirth’s Modification for Maximum Likelihood EstimationRobust Sandwich Variance EstimateTesting the Global Null HypothesisType 3 Tests and Joint TestsConfidence Limits for a Hazard RatioUsing the TEST Statement to Test Linear HypothesesAnalysis of Multivariate Failure Time DataModel Fit StatisticsSchemper-Henderson Predictive MeasureResidualsDiagnostics Based on Weighted ResidualsInfluence of Observations on Overall Fit of the ModelSurvivor Function EstimatorsCaution about Using Survival Data with Left TruncationEffect Selection MethodsAssessment of the Proportional Hazards ModelThe Penalized Partial Likelihood Approach for Fitting Frailty ModelsSpecifics for Bayesian AnalysisComputational ResourcesInput and Output Data SetsDisplayed OutputODS Table NamesODS Graphics
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ExamplesStepwise RegressionBest Subset SelectionModeling with Categorical PredictorsFirth’s Correction for Monotone LikelihoodConditional Logistic Regression for m:n MatchingModel Using Time-Dependent Explanatory VariablesTime-Dependent Repeated Measurements of a CovariateSurvival CurvesAnalysis of ResidualsAnalysis of Recurrent Events DataAnalysis of Clustered DataModel Assessment Using Cumulative Sums of Martingale ResidualsBayesian Analysis of the Cox ModelBayesian Analysis of Piecewise Exponential ModelAnalysis of Competing-Risks Data
- References
Consider a set of n subjects such that the counting process 
for the ith subject represents the number of observed events experienced over time t. The sample paths of the process 
are step functions with jumps of size 
, with 
. Let 
denote the vector of unknown regression coefficients. The multiplicative hazards function 
for 
is given by
![\[ Y_{i}(t)d\Lambda (t,{\bZ }_{i}(t)) = Y_{i}(t)\exp (\bbeta ’\bZ _{i}(t)) d\Lambda _{0}(t) \]](images/statug_phreg0236.png){kind=small}
where
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indicates whether the ith subject is at risk at time t (specifically, 
if at risk and 
otherwise)
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is the vector of explanatory variables for the ith subject at time t
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is an unspecified baseline hazard function
See Fleming and Harrington (1991) and Andersen et al. (1992). The Cox model is a special case of this multiplicative hazards model, where until the first event or censoring, and thereafter.
The partial likelihood for n independent triplets 
, has the form
![\[ \mc{L}(\bbeta ) = \prod _{i=1}^{n} \prod _{t \geq 0} \biggl \{ \frac{Y_{i}(t)\exp (\bbeta '\bZ _{i}(t))}{\sum _{j=1}^{n}Y_{j}(t)\exp (\bbeta '\bZ _{j}(t))} \biggr \} ^{\Delta N_{i}(t)} \]](images/statug_phreg0243.png){kind=small}
where 
if 
, and 
otherwise.