Mean Time Between Failure (MTBF) and Its Importance to Device and System Design

November 4, 2020 Cadence PCB Solutions

Key Takeaways

●  Define Mean Time Between Failure (MTBF).

●  Gain a greater understanding of the importance of MTBF.

●  Learn how assessments like MTBF translate into better designs, functionality, and life cycles for devices and systems.

 Mean Time Between Failure (MTBF) is a productive maintenance and management tool.

Mean Time Between Failure (MTBF)

In every conceivable field or area of specialization, designs typically trend toward longevity or, to some degree, increased device life cycle. In printed circuit board assembly (PCBA), the demand for increased life cycles, performance, functionality, and of course, reliability is inherently part of the overall design process.

Therefore, it is only logical that there is a need to analyze or assess the reliability of mechanical and electrical devices or systems in terms of failure rates and time to fail. One such assessment is a metric called Mean Time Between Failure (MTBF). In this article, we’ll take a closer look at what MTBF is, how to calculate it, and why it’s important to your overall PCB design. 

What is Mean Time Between Failure?

Mean Time Between Failure (MTBF) or failures, as some say, is the projected elapsed time between intrinsic failure of electronic and mechanical devices or systems. In other words, the average amount of time until the device or system breaks. Typically, this is during standard system operation. Furthermore, we generally only apply the term, MTBF, to repairable systems. However, we utilize the term, mean time to failure (MTTF) to non-repairable devices or systems which assess the expected time to failure.

Also, MTBF's definition is dependent upon conditions of the device or system under assessment and what constitutes a failure. In most cases, a complex and repairable system defines failure as an event that removes the device or system from service, i.e., in need of repair. So this is not a total loss. If a device remains operable, it’s not classified as a failure so long as the device can maintain functionality in its unrepaired state. 

Additionally, devices that you remove from service for routine planned maintenance or inventory control also are not classified as failures. The general rule of thumb is, the higher the MTBF, the longer a system is likely to function before failures occur.

Calculating Mean Time Between Failure

Typically, MTBF is measured in hours. And since MTBF is the arithmetic mean or average amount of time between failures of an electronic or mechanical system, there is a simple way to calculate it: 

  • Divide the total number of operational hours within a specific timeframe by the number of failures that occur within this period. 

For example, a Smartphone can operate for 1,095 hours in a year or 4 hours per day for 365 days. However, the Smartphone fails a total of ten times within this timeframe.

So, let us now calculate the MTBF:

MTBF = (4 hours per day × 365 days) ÷ 10 breakdowns = 146 hours

MTBF = 1460 hours ÷ 10 breakdowns = 146 hours

MTBF = 146 hours

The example above is MTBF in its simplest form. However, these calculations tend to be more complicated when dealing with various failure metrics. This becomes more evident when you analyze extended amounts of time with multiple issues occurring, which will obviously require more steps when performing your calculations.

The following example is a more complex calculation for MTBF involving an extended use per day timeframe and multiple issue occurrences: The same Smartphone is in use 10 hours per day, but it suffers a failure twice in 14 days (140 hours). 

  1. The first issue occurs after 40 hours from the initial start time and takes 4 hours to repair. This, of course, means that our first period of uptime lasts for 40 hours. 

  2. Now, our second issue occurs 80 hours from the start time and took 2 hours to repair. Therefore, because the first issue occurred after 40 hours of uptime and took 4 hours to repair, the second failure transpires after 36 hours of uptime (80 - 44 = 36).

  3. The second issue takes 2 hours to repair, leaving 58 (140 - 76) hours of uptime. The values utilized in the MTBF formula is as follows:

MTBF = (40 hours + 36 hours + 58 hours) ÷ 2 failures

MTBF = (134 hours) ÷ 2 failures = 67 hours

MTBF = 67 hours

We can now see that the MTBF is equal to the total uptime for a particular device or system.

A Comparison of MTBF, MTTR, MTTF, and FIT

MTBF: is the arithmetic mean or the average amount of time between failures. Still, the concepts that follow are a few other assessments that help to give a clearer picture of a device or system's overall level of reliability. 

MTTR (mean time to repair): is the time required to repair a hardware module suffering from failure. Typically when a device or system fails, it is a hardware component that needs replacement or repair. The longer it takes to repair a device or system, the more cost you incur due to downtime.

MTTF (mean time to failure): is a fundamental measure of the reliability of non-repairable systems. In summary, it is the arithmetic mean time one can expect before the first failure of a device, system, or piece of equipment.

FIT (failure in time): is an alternative method of disclosing MTBF. FIT details the number of failures one can expect per one billion hours of operation of a device. Also, FIT encounters widespread use in both the semiconductor industry and the component manufacturing industry.

Applications of Mean Time Between Failure

We utilize the MTBF value to assess a device or system's overall reliability. This assessment is even more critical to manufacturers and companies that produce products. In general, this value is not a quantitative way to differentiate between failed and working devices, but rather an average or mean device life cycle.

Because MTBF is an expression of device life-expectancy, its value estimate is an essential component in product development, and design and reliability engineers typically utilize reliability software to calculate a device's MTBF under various standards. These standards include Siemens SN29500, MIL-HDBK-217F, FIDES, Telcordia sr-332, and RDF 2000/UTE C 80-810.

In the manufacturing industry, a company’s ability to understand its device or system’s reliability enables them to receive valuable feedback to help increase the life expectancy of their equipment. This knowledge ultimately leads to improved design accuracy, cost-effectiveness, and reduced material waste.

Accurate MTBF assessments of life-critical equipment saves lives.

Intensive care emergency room with artificial lung ventilation monitor

With the right set of PCB layout and design software, your designers and production teams should be able to calculate MTBF easily with plug-in prediction capabilities. Allegro PCB Editor and Cadence's full suite of design tools can help you create reliable designs from verified component models and analyze all aspects of its functionality. You will also have access to a set of tools for MCAD design and preparing for manufacturing.

If you're looking to learn more about how Cadence has the solution for you, talk to us and our team of experts.

 

About the Author

Cadence PCB solutions is a complete front to back design tool to enable fast and efficient product creation. Cadence enables users accurately shorten design cycles to hand off to manufacturing through modern, IPC-2581 industry standard.

Follow on Linkedin Visit Website More Content by Cadence PCB Solutions
Previous Article
 Conformal Coating Process
Conformal Coating Process

Conformal coating is a process that covers a PCB or component with a protective film barrier against mechan...

Next Article
Working with a Shunt Voltage Regulator in Your PCB Layout
Working with a Shunt Voltage Regulator in Your PCB Layout

A shunt voltage regulator gives you a simple way to build a linear regulator with reasonably high efficiency.

Allegro PCB Editor: The Ultimate PCB Design Experience

Request a Demo