Mean time between failures

Mean time between failures (MTBF) describes the expected time between two failures for a repairable system. For example, three identical systems starting to function properly at time 0 are working until all of them fail. The first system fails after 100 hours, the second after 120 hours and the third after 130 hours. The MTBF of the systems is the average of the three failure times, which is 116.667 hours. If the systems were non-repairable, then theirMTTFwould be 116.667 hours.

In general, MTBF is the "up-time" between two failure states of a repairable system during operation as outlined here:

For each observation, the "down time" is the instantaneous time it went down, which is after (i.e. greater than) the moment it went up, the "up time". The difference ( "down time" minus "up time" ) is the amount of time it was operating between these two events.

By referring to the figure above, the MTBF of a component is the sum of the lengths of the operational periods divided by the number of observed failures:

${\displaystyle {\text{MTBF}}={\frac {\sum {({\text{start of downtime}}-{\text{start of uptime}})}}{\text{number of failures}}}.}$

In a similar manner, mean down time (MDT) can be defined as

${\displaystyle {\text{MDT}}={\frac {\sum {({\text{start of uptime}}-{\text{start of downtime}})}}{\text{number of failures}}}.}$

The MTBF is the expected value of the random variable${\displaystyle T}$indicating the time until failure. Thus, it can be written as^[4]

${\displaystyle {\text{MTBF}}=\mathbb {E} \{T\}=\int _{0}^{\infty }tf_{T}(t)\,dt}$

where${\displaystyle f_{T}(t)}$is theprobability density functionof${\displaystyle T}$.Equivalently, the MTBF can be expressed in terms of thereliability function${\displaystyle R_{T}(t)}$as

${\displaystyle {\text{MTBF}}=\int _{0}^{\infty }R(t)\,dt}$.

The MTBF and${\displaystyle T}$have units of time (e.g., hours).

Any practically-relevant calculation of the MTBF assumes that the system is working within its "useful life period", which is characterized by a relatively constantfailure rate(the middle part of the "bathtub curve") when only random failures are occurring.^[1]In other words, it is assumed that the system has survived initial setup stresses and has not yet approached its expected end of life, both of which often increase the failure rate.

Assuming a constant failure rate${\displaystyle \lambda }$implies that${\displaystyle T}$has anexponential distributionwith parameter${\displaystyle \lambda }$.Since the MTBF is the expected value of${\displaystyle T}$,it is given by the reciprocal of the failure rate of the system,^[1][4]

${\displaystyle {\text{MTBF}}={\frac {1}{\lambda }}}$.

Once the MTBF of a system is known, and assuming a constant failure rate, theprobabilitythat any one particular system will be operational for a given duration can be inferred^[1]from thereliability functionof theexponential distribution,${\displaystyle R_{T}(t)=e^{-\lambda t}}$.In particular, the probability that a particular system will survive to its MTBF is${\displaystyle 1/e}$,or about 37% (i.e., it will fail earlier with probability 63%).^[5]

The MTBF value can be used as a system reliability parameter or to compare different systems or designs. This value should only be understood conditionally as the “mean lifetime” (an average value), and not as a quantitative identity between working and failed units.^[1]

Since MTBF can be expressed as “average life (expectancy)”, many engineers assume that 50% of items will have failed by timet= MTBF. This inaccuracy can lead to bad design decisions. Furthermore, probabilistic failure prediction based on MTBF implies the total absence of systematic failures (i.e., a constant failure rate with only intrinsic, random failures), which is not easy to verify.^[4]Assuming no systematic errors, the probability the system survives during a duration, T, is calculated as exp^(-T/MTBF). Hence the probability a system fails during a duration T, is given by 1 - exp^(-T/MTBF).

MTBF value prediction is an important element in the development of products. Reliability engineers and design engineers often use reliability software to calculate a product's MTBF according to various methods and standards (MIL-HDBK-217F, Telcordia SR332, Siemens SN 29500, FIDES, UTE 80-810 (RDF2000), etc.). The Mil-HDBK-217 reliability calculator manual in combination with RelCalc software (or other comparable tool) enables MTBF reliability rates to be predicted based on design.

A concept which is closely related to MTBF, and is important in the computations involving MTBF, is themean down time(MDT). MDT can be defined as mean time which the system is down after the failure. Usually, MDT is considered different from MTTR (Mean Time To Repair); in particular, MDT usually includes organizational and logistical factors (such as business days or waiting for components to arrive) while MTTR is usually understood as more narrow and more technical.

MTBF serves as a crucial metric for managing machinery and equipment reliability. Its application is particularly significant in the context oftotal productive maintenance(TPM), a comprehensive maintenance strategy aimed at maximizing equipmenteffectiveness.MTBF provides a quantitative measure of the time elapsed between failures of a system during normal operation, offering insights into the reliability and performance of manufacturing equipment.^[6]

By integrating MTBF with TPM principles, manufacturers can achieve a more proactive maintenance approach. This synergy allows for the identification of patterns and potential failures before they occur, enabling preventive maintenance and reducing unplanned downtime. As a result, MTBF becomes akey performance indicator(KPI) within TPM, guiding decisions on maintenance schedules, spare parts inventory, and ultimately, optimizing the lifespan and efficiency of machinery.^[7]This strategic use of MTBF within TPM frameworks enhances overall production efficiency, reduces costs associated with breakdowns, and contributes to the continuous improvement of manufacturing processes.

Two components${\displaystyle c_{1},c_{2}}$(for instance hard drives, servers, etc.) may be arranged in a network, inseriesor inparallel.The terminology is here used by close analogy to electrical circuits, but has a slightly different meaning. We say that the two components are in series if the failure ofeithercauses the failure of the network, and that they are in parallel if only the failure ofbothcauses the network to fail. The MTBF of the resulting two-component network with repairable components can be computed according to the following formulae, assuming that the MTBF of both individual components is known:^[8][9]

${\displaystyle {\text{mtbf}}(c_{1};c_{2})={\frac {1}{{\frac {1}{{\text{mtbf}}(c_{1})}}+{\frac {1}{{\text{mtbf}}(c_{2})}}}}={\frac {{\text{mtbf}}(c_{1})\times {\text{mtbf}}(c_{2})}{{\text{mtbf}}(c_{1})+{\text{mtbf}}(c_{2})}}\;,}$

where${\displaystyle c_{1};c_{2}}$is the network in which the components are arranged in series.

For the network containing parallel repairable components, to find out the MTBF of the whole system, in addition to component MTBFs, it is also necessary to know their respective MDTs. Then, assuming that MDTs are negligible compared to MTBFs (which usually stands in practice), the MTBF for the parallel system consisting from two parallel repairable components can be written as follows:^[8][9]

${\displaystyle {\begin{aligned}{\text{mtbf}}(c_{1}\parallel c_{2})&={\frac {1}{{\frac {1}{{\text{mtbf}}(c_{1})}}\times {\text{PF}}(c_{2},{\text{mdt}}(c_{1}))+{\frac {1}{{\text{mtbf}}(c_{2})}}\times {\text{PF}}(c_{1},{\text{mdt}}(c_{2}))}}\\[1em]&={\frac {1}{{\frac {1}{{\text{mtbf}}(c_{1})}}\times {\frac {{\text{mdt}}(c_{1})}{{\text{mtbf}}(c_{2})}}+{\frac {1}{{\text{mtbf}}(c_{2})}}\times {\frac {{\text{mdt}}(c_{2})}{{\text{mtbf}}(c_{1})}}}}\\[1em]&={\frac {{\text{mtbf}}(c_{1})\times {\text{mtbf}}(c_{2})}{{\text{mdt}}(c_{1})+{\text{mdt}}(c_{2})}}\;,\end{aligned}}}$

where${\displaystyle c_{1}\parallel c_{2}}$is the network in which the components are arranged in parallel, and${\displaystyle PF(c,t)}$is the probability of failure of component${\displaystyle c}$during "vulnerability window"${\displaystyle t}$.

Intuitively, both these formulae can be explained from the point of view of failure probabilities. First of all, let's note that the probability of a system failing within a certain timeframe is the inverse of its MTBF. Then, when considering series of components, failure of any component leads to the failure of the whole system, so (assuming that failure probabilities are small, which is usually the case) probability of the failure of the whole system within a given interval can be approximated as a sum of failure probabilities of the components. With parallel components the situation is a bit more complicated: the whole system will fail if and only if after one of the components fails, the other component fails while the first component is being repaired; this is where MDT comes into play: the faster the first component is repaired, the less is the "vulnerability window" for the other component to fail.

Using similar logic, MDT for a system out of two serial components can be calculated as:^[8]

${\displaystyle {\text{mdt}}(c_{1};c_{2})={\frac {{\text{mtbf}}(c_{1})\times {\text{mdt}}(c_{2})+{\text{mtbf}}(c_{2})\times {\text{mdt}}(c_{1})}{{\text{mtbf}}(c_{1})+{\text{mtbf}}(c_{2})}}\;,}$

and for a system out of two parallel components MDT can be calculated as:^[8]

${\displaystyle {\text{mdt}}(c_{1}\parallel c_{2})={\frac {{\text{mdt}}(c_{1})\times {\text{mdt}}(c_{2})}{{\text{mdt}}(c_{1})+{\text{mdt}}(c_{2})}}\;.}$

Through successive application of these four formulae, the MTBF and MDT of any network of repairable components can be computed, provided that the MTBF and MDT is known for each component. In a special but all-important case of several serial components, MTBF calculation can be easily generalised into

${\displaystyle {\text{mtbf}}(c_{1};\dots;c_{n})=\left(\sum _{k=1}^{n}{\frac {1}{{\text{mtbf}}(c_{k})}}\right)^{-1}\;,}$

which can be shown by induction,^[10]and likewise

${\displaystyle {\text{mdt}}(c_{1}\parallel \dots \parallel c_{n})=\left(\sum _{k=1}^{n}{\frac {1}{{\text{mdt}}(c_{k})}}\right)^{-1}\;,}$

since the formula for the mdt of two components in parallel is identical to that of the mtbf for two components in series.

There are many variations of MTBF, such asmean time between system aborts(MTBSA),mean time between critical failures(MTBCF) ormean time between unscheduled removal(MTBUR). Such nomenclature is used when it is desirable to differentiate among types of failures, such as critical and non-critical failures. For example, in an automobile, the failure of the FM radio does not prevent the primary operation of the vehicle.

It is recommended to useMean time to failure(MTTF) instead of MTBF in cases where a system is replaced after a failure ( "non-repairable system" ), since MTBF denotes time between failures in a system which can be repaired.^[1]

MTTFdis an extension of MTTF, and is only concerned about failures which would result in a dangerous condition. It can be calculated as follows:

${\displaystyle {\begin{aligned}{\text{MTTF}}&\approx {\frac {B_{10}}{0.1n_{\text{onm}}}},\\[8pt]{\text{MTTFd}}&\approx {\frac {B_{10d}}{0.1n_{\text{op}}}},\end{aligned}}}$

whereB₁₀is the number of operations that a device will operate prior to 10% of a sample of those devices would fail andn_opis number of operations.B_10dis the same calculation, but where 10% of the sample would fail to danger.n_opis the number of operations/cycle in one year.^[11]

In fact the MTBF counting only failures with at least some systems still operating that have not yet failed underestimates the MTBF by failing to include in the computations the partial lifetimes of the systems that have not yet failed. With such lifetimes, all we know is that the time to failure exceeds the time they've been running. This is calledcensoring.In fact with a parametric model of the lifetime, thelikelihood for the experience on any given day is as follows:

${\displaystyle L=\prod _{i}\lambda (u_{i})^{\delta _{i}}S(u_{i})}$,

where

${\displaystyle u_{i}}$is the failure time for failures and the censoring time for units that have not yet failed,

${\displaystyle \delta _{i}}$= 1 for failures and 0 for censoring times,

${\displaystyle S(u_{i})}$= the probability that the lifetime exceeds${\displaystyle u_{i}}$,called the survival function, and

${\displaystyle \lambda (u_{i})=f(u)/S(u)}$is called thehazard function,the instantaneous force of mortality (where${\displaystyle f(u)}$= the probability density function of the distribution).

For a constantexponential distribution,the hazard,${\displaystyle \lambda }$,is constant. In this case, the MBTF is

MTBF =${\displaystyle 1/{\hat {\lambda }}=\sum u_{i}/k}$,

where${\displaystyle {\hat {\lambda }}}$is the maximum likelihood estimate of${\displaystyle \lambda }$,maximizing the likelihood given above and${\displaystyle k=\sum \sigma _{i}}$is the number of uncensored observations.

We see that the difference between the MTBF considering only failures and the MTBF including censored observations is that the censoring times add to the numerator but not the denominator in computing the MTBF.^[12]

• "Reliability and Availability Basics".EventHelix.
• Speaks, Scott (2005)."Reliability and MTBF Overview"(PDF).Vicor Reliability Engineering.
• "Failure Rates, MTBF, and All That".MathPages.
• "Simple Guide to MTBF: What It Is and When To use It".Road to Reliability. 10 December 2021.
• "What is Mean Time to Failure and How Do We Calculate?".NEXGEN. 21 June 2023.