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'''Survival analysis''' is a branch of [[statistics]] which deals with analysis of time duration to until one or more events happen, such as death in biological organisms and failure in mechanical systems. This topic is called ''[[reliability theory]]'' or ''reliability analysis'' in [[engineering]], and ''duration analysis'' or ''duration modeling'' in [[economics]] or ''event history analysis'' in [[sociology]]. Survival analysis attempts to answer questions such as: what is the proportion of a population which will survive past a certain time? Of those that survive, at what rate will they die or fail? Can multiple causes of death or failure be taken into account? How do particular circumstances or characteristics increase or decrease the probability of survival?
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To answer such questions, it is necessary to define "lifetime". In the case of biological survival, [[death]] is unambiguous, but for mechanical reliability, [[failure]] may not be well-defined, for there may well be mechanical systems in which failure is partial, a matter of degree, or not otherwise localized in [[time]]. Even in biological problems, some events (for example, [[myocardial infarction|heart attack]] or other organ failure) may have the same ambiguity. The [[theory]] outlined below assumes well-defined events at specific times; other cases may be better treated by models which explicitly account for ambiguous events.
 
More generally, survival analysis involves the modeling of time to event data; in this context, death or failure is considered an "event" in the survival analysis literature – traditionally only a single event occurs for each subject, after which the organism or mechanism is dead or broken.  ''Recurring event'' or ''repeated event'' models relax that assumption. The study of recurring events is relevant in [[systems reliability]], and in many areas of social sciences and medical research.
 
==General formulation==
 
===Survival function===
{{main|survival function}}
The object of primary interest is the '''survival function''', conventionally denoted ''S'', which is defined as
 
:<math>S(t) = \Pr(T > t)</math>
 
where ''t'' is some time, ''T'' is a [[random variable]] denoting the time of death, and "Pr" stands for [[probability]]. That is, the survival function is the probability that the time of death is later than some specified time ''t''.
The survival function is also called the ''survivor function'' or ''survivorship function'' in problems of biological survival, and the ''reliability function'' in mechanical survival problems. In the latter case, the reliability function is denoted ''R''(''t'').
 
Usually one assumes ''S''(0) = 1, although it could be less than 1 if there is the possibility of immediate death or failure.
 
The survival function must be non-increasing: ''S''(''u'') ≤ ''S''(''t'') if ''u'' ≥ ''t''. This property follows directly because ''T''>''u'' implies ''T''>''t''. This reflects the notion that survival to a later age is only possible if all younger ages are attained. Given this property, the lifetime distribution function and event density (''F'' and ''f'' below) are well-defined.
 
The survival function is usually assumed to approach zero as age increases without bound, i.e., ''S''(''t'') → 0 as ''t'' → ∞, although the limit could be greater than zero if eternal life is possible. For instance, we could apply survival analysis to a mixture of stable and unstable [[Carbon#Isotopes|carbon isotopes]]; unstable isotopes would decay sooner or later, but the stable isotopes would last indefinitely.
 
===Lifetime distribution function and event density===
 
Related quantities are defined in terms of the survival function.
 
The '''lifetime distribution function''', conventionally denoted ''F'', is defined as the complement of the survival function,
 
:<math>F(t) = \Pr(T \le t) = 1 - S(t).</math>
 
If ''F'' is [[differentiable]] then the derivative, which is the density function of the lifetime distribution, is conventionally denoted ''f'',
 
:<math>f(t) = F'(t) = \frac{d}{dt} F(t).</math>
 
The function ''f'' is sometimes called the '''event density'''; it is the rate of death or failure events per unit time.
 
The survival function can be expressed in terms of [[probability distribution]] and [[probability density function]]s
 
:<math>S(t) = \Pr(T > t) = \int_t^{\infty} f(u)\,du = 1-F(t).</math>
 
Similarly, a survival event density function can be defined as
 
:<math>s(t) = S'(t) = \frac{d}{dt} S(t) = \frac{d}{dt} \int_t^{\infty} f(u)\,du = \frac{d}{dt} [1-F(t)] = -f(t).</math>
 
===Hazard function and cumulative hazard function===
 
The '''[[hazard function]]''', conventionally denoted <math>\lambda</math>, is defined as the event rate at time ''t'' conditional on survival until time ''t'' or later (that is, ''T'' ≥ ''t''),
 
:<math>\lambda(t) = \lim_{dt \rightarrow 0} \frac{\Pr(t \leq T < t+dt\,|\,T \geq t)}{dt} = \frac{f(t)}{S(t)} = -\frac{S'(t)}{S(t)}.</math>
 
[[Force of mortality]] is a synonym of ''hazard function'' which is used particularly in [[demography]] and [[actuarial science]], where it is denoted by <math>\mu</math>. The term ''hazard rate'' is another synonym.
 
The hazard function must be non-negative, λ(''t'') ≥ 0, and its integral over <math>[0, \infty]</math> must be infinite, but is not otherwise constrained; it may be increasing or decreasing, non-monotonic, or discontinuous.
An example is the [[bathtub curve]] hazard function, which is large for small values of ''t'', decreasing to some minimum, and thereafter increasing again; this can model the property of some mechanical systems to either fail soon after operation, or much later, as the system ages.
 
The hazard function can alternatively be represented in terms of the '''cumulative hazard function''', conventionally denoted <math>\Lambda</math>:
 
:<math>\,\Lambda(t) = -\log S(t)</math>
 
so transposing signs and exponentiating
 
:<math>\,S(t) = \exp(-\Lambda(t))</math>
 
or differentiating (with the chain rule)
 
:<math>\frac{d}{dt} \Lambda(t) = -\frac{S'(t)}{S(t)} = \lambda(t).</math>
 
The name "cumulative hazard function" is derived from the fact that
 
:<math> \Lambda(t) = \int_0^{t} \lambda(u)\,du</math>
 
which is the "accumulation" of the hazard over time.
 
From the definition of <math>\Lambda(t)</math>, we see that it increases without bound as ''t'' tends to infinity (assuming that ''S''(''t'') tends to zero). This implies that <math>\lambda(t)</math> must not decrease too quickly, since, by definition, the cumulative hazard has to diverge. For example, <math>\exp(-t)</math> is not the hazard function of any survival distribution, because its integral converges to 1.
 
===Quantities derived from the survival distribution===
 
'''Future lifetime''' at a given time <math>t_0</math> is the time remaining until death, given survival to age <math>t_0</math>. Thus, it is <math>T - t_0</math> in the present notation. The '''expected future lifetime''' is the [[expected value]] of future lifetime. The probability of death at or before age <math>t + t_0</math>, given survival until age <math>t_0</math>, is just
 
:<math>P(T \le t_0 + t | T > t_0) = \frac{P(t_0 < T \le t_0 + t)}{P(T > t_0)} = \frac{F(t_0 + t) - F(t_0)}{S(t_0)}.</math>
 
Therefore the probability density of future lifetime is
 
:<math>\frac{d}{dt}\frac{F(t_0 + t) - F(t_0)}{S(t_0)} = \frac{f(t_0 + t)}{S(t_0)}</math>
 
and the expected future lifetime is
 
:<math>\frac{1}{S(t_0)} \int_0^{\infty} t\,f(t+t_0)\,dt = \frac{1}{S(t_0)} \int_{t_0}^{\infty} S(t)\,dt,</math>
 
where the second expression is obtained using [[integration by parts]].
 
For <math>t_0 = 0</math>, that is, at birth, this reduces to the expected lifetime.
 
In reliability problems, the expected lifetime is called the ''[[mean time to failure]]'', and the expected future lifetime is called the ''mean residual lifetime''.
 
As the probability of an individual surviving until age ''t'' or later is ''S''(''t''), by definition, the expected number of survivors at age ''t'' out of an initial [[population]] of ''n'' newborns is ''n'' × ''S''(''t''), assuming the same survival function for all individuals. Thus the expected proportion of survivors is ''S''(''t'').
If the survival of different individuals is independent, the number of survivors at age ''t'' has a [[binomial distribution]] with parameters ''n'' and ''S''(''t''), and the [[variance]] of the proportion of survivors is ''S''(''t'') ×  (1-''S''(''t''))/''n''.
 
The age at which a specified proportion of survivors remain can be found by solving the equation ''S''(''t'') = ''q'' for ''t'', where ''q'' is the [[quantile]] in question. Typically one is interested in the '''[[median]] lifetime''', for which ''q'' = 1/2, or other quantiles such as ''q'' = 0.90 or ''q'' = 0.99.
 
One can also make more complex inferences from the survival distribution. In mechanical reliability problems, one can bring cost (or, more generally, [[utility]]) into consideration, and thus solve problems concerning repair or replacement. This leads to the study of [[renewal theory]] and [[reliability theory of aging and longevity]].
 
==Censoring==
[[Censoring (statistics)|Censoring]] is a form of missing data problem which is common in survival analysis. Ideally, both the birth and death dates of a subject are known, in which case the lifetime is known.
 
If it is known only that the date of death is after some date, this is called ''right censoring''. Right censoring  will occur for those subjects whose birth date is known but who are still alive when they are lost to follow-up or when the study ends.
 
If a subject's lifetime is known to be less than a certain duration, the lifetime is said to be ''left-censored''.
 
It may also happen that subjects with a lifetime less than some threshold may not be observed at all: this is called ''truncation''. Note that truncation is different from left censoring, since for a left censored datum, we know the subject exists, but for a truncated datum, we may be completely unaware of the subject. Truncation is also common. In a so-called ''delayed entry'' study, subjects are not observed at all until they have reached a certain age. For example, people may not be observed until they have reached the age to enter school. Any deceased subjects in the pre-school age group would be unknown.  Left-truncated data are common in actuarial work for life insurance and pensions.<ref>{{cite journal |last=Richards |first=S. J. |title=A handbook of parametric survival models for actuarial use |journal=Scandinavian Actuarial Journal |volume=2012 |year=2012 |issue=4 |pages=233–257 |doi=10.1080/03461238.2010.506688 }}</ref>
 
We generally encounter right-censored data. Left-censored data can occur when a person's survival time becomes incomplete on the left side of the follow-up period for the person. As an example, we may follow up a patient for any infectious disorder from the time of his or her being tested positive for the infection. We may never know the exact time of exposure to the infectious agent.<ref>{{cite journal |last=Singh |first=R. |last2=Mukhopadhyay |first2=K. |title=Survival analysis in clinical trials: Basics and must know areas |journal=[[Perspectives in Clinical Research|Perspect Clin Res]] |year=2011 |volume=2 |issue=4 |pages=145–148 |doi=10.4103/2229-3485.86872 }}</ref>
 
==Fitting parameters to data==
Survival models can be usefully viewed as ordinary regression models in which the response variable is time.  However, computing the likelihood function (needed for fitting parameters or making other kinds of inferences) is complicated by the censoring. The [[likelihood function]] for a survival model, in the presence of censored data, is formulated as follows. By definition the likelihood function is the conditional probability of the data given the parameters of the model.
It is customary to assume that the data are independent given the parameters. Then the likelihood function is the product of the likelihood of each datum. It is convenient to partition the data into four categories: uncensored, left censored, right censored, and interval censored. These are denoted "unc.", "l.c.", "r.c.", and "i.c." in the equation below.
 
:<math> L(\theta) = \prod_{T_i\in unc.} \Pr(T = T_i|\theta)
  \prod_{i\in l.c.} \Pr(T < T_i|\theta)
  \prod_{i\in r.c.} \Pr(T > T_i|\theta)
  \prod_{i\in i.c.} \Pr(T_{i,l} < T < T_{i,r}|\theta) .</math>
 
For an uncensored datum, with <math>T_i</math> equal to the age at death, we have
 
:<math> \Pr(T = T_i|\theta) = f(T_i|\theta) .</math>
 
For a left censored datum, such that the age at death is known to be less than <math>T_i</math>, we have
 
:<math> \Pr(T < T_i|\theta) = F(T_i|\theta) = 1 - S(T_i|\theta) .</math>
 
For a right censored datum, such that the age at death is known to be greater than <math>T_i</math>, we have
 
:<math> \Pr(T > T_i|\theta) = 1 - F(T_i|\theta) = S(T_i|\theta) .</math>
 
For an interval censored datum, such that the age at death is known to be less than <math>T_{i,r}</math> and greater than <math>T_{i,l}</math>, we have
 
:<math> \Pr(T_{i,l} < T < T_{i,r}|\theta)
= S(T_{i,l}|\theta) - S(T_{i,r}|\theta) .</math>
 
An important application where interval censored data arises is current status data, where the actual occurrence of an event <math> T_i</math> is only known to the extent that it known not to occurred before observation time and to have occurred before the next.
 
==Non-parametric estimation==
 
The [[Nelson–Aalen estimator]] can be used to provide a [[non-parametric statistics|non-parametric]] estimate of the cumulative hazard rate function.
 
==Distributions used in survival analysis==
* [[Exponential distribution]]
* [[Weibull distribution]]
* [[Log-logistic distribution]]
* [[Gamma distribution]]
* [[Exponential-logarithmic distribution]]
 
==See also==
{{Columns-list|2|
* [[Kaplan–Meier estimator]]
* [[Survival rate]]
* [[Reliability theory]]
* [[Proportional hazards models]]
* [[Accelerated failure time model]]
* [[Failure rate]]
* [[Logrank test]]
* [[Survival function]]
* [[MTBF]]
* [[Censoring (statistics)]]
* [[Maximum likelihood]]
* [[Cell survival curve]]
}}
 
==References==
{{reflist}}
 
==Further reading==
*{{cite book |first=David |last=Collett |title=Modelling Survival Data in Medical Research |edition=Second |location=Boca Raton |publisher=Chapman & Hall/CRC |year=2003 |isbn=1584883251 }}
*{{cite book |first=Regina |last=Elandt-Johnson |first2=Norman |last2=Johnson |title=Survival Models and Data Analysis |location=New York |publisher=John Wiley & Sons |year=1999 |isbn=0471349925 }}
*{{cite book |first=J. D. |last=Kalbfleisch |first2=Ross L. |last2=Prentice |title=The statistical analysis of failure time data |location=New York |publisher=John Wiley & Sons |year=2002 |isbn=047136357X }}
*{{cite book |first=Jerald F. |last=Lawless |title=Statistical Models and Methods for Lifetime Data |edition=2nd |publisher=John Wiley and Sons |location=Hoboken |year=2003 |isbn=0471372153 }}
*{{cite book |last=Rausand |first=M. |last2=Hoyland |first2=A. |title=System Reliability Theory: Models, Statistical Methods, and Applications |publisher=John Wiley & Sons |location=Hoboken |year=2004 |isbn=047147133X }}
 
==External links==
*{{cite web |first=Terry |last=Therneau |title=A Package for Survival Analysis in S |url=http://www.mayo.edu/hsr/people/therneau/survival.ps }} At: http://mayoresearch.mayo.edu/mayo/research/biostat/therneau.cfm
*{{cite web |title=Engineering Statistics Handbook |publisher=NIST/SEMATEK |url=http://www.itl.nist.gov/div898/handbook/ }}
* [[SOCR]], [http://www.socr.ucla.edu/htmls/ana/Survival_Analysis.html Survival analysis applet] and [http://wiki.stat.ucla.edu/socr/index.php/SOCR_EduMaterials_AnalysisActivities_Survival interactive learning activity].
* [http://www.statsoft.com/textbook/stsurvan.html Survival/Failure Time Analysis] @ [[Statistics]]' [http://www.statsoft.com/textbook/ Textbook Page]
* [http://www.netstorm.be/home/survival Survival Analysis in R]
* [http://www.nag.co.uk/numeric/fl/nagdoc_fl24/html/G12/g12conts.html Survival Analysis in NAG Fortran Library]
 
 
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{{DEFAULTSORT:Survival Analysis}}
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Latest revision as of 10:46, 5 December 2014

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