From the functionality of medical alert devices to measuring proper acceleration or g-force, one needs an accelerometer. However, this small device doesn’t measure what most people think of as acceleration (an increase in speed). Instead, accelerometer’s measure what scientists consider proper acceleration, or the acceleration of an object relative to inertia or free-fall. One example of how this is different from velocity is that if an accelerometer is placed on the ground, it will actually show a measurement because the Earth has a gravitational pull. Because an accelerometer takes a measurement of an object relative to inertia, it must have some form of object to measure. Therefore, an accelerometer that is released in free fall actually records a measurement of zero, even if it’s being pulled forward by the Earth’s gravity.
There have been a number of different types of accelerometers created over the years. The first device to truly be considered an accelerometer sensor was built in 1923. It was a resistance-bridge-type accelerometer. Five years later, the device was commercialized by Southwark, a U. S.-based company. They later created a two-axis accelerometer. Other versions, including a strain gage accelerometer, a Rochelle salt crystal accelerometer, and a Barium Titanate accelerometer, were later created. Today, three axis accelerometers are incredibly common in electronic devices and can be found in smartphones, tablets, video game controllers, and fall automatic detection devices which are widely used in the medical alert industry.
- Accelerometer Development Timeline – A simple history of the accelerometer.
- The Accelerometer – Wiki’s entry on the device.
- Overview of the Accelerometer – Its history, uses, and more.
- A Beginner’s Guide to Accelerometers – A basic outline of the device.
- What are Accelerometers? – Information from Omega Process Measurement & Control.
Accelerometers in Aircraft and Missiles
Accelerometers are used in a number of different products, including aircraft and missiles. One of the most common uses of accelerometers is to determine the aircraft’s pitch orientation, or its orientation relative to the curve of the Earth. Aircraft have to account for this pitch because the Earth is round—if pilots didn’t correct the plane’s orientation, it would eventually fly into the upper atmosphere and into space (or crash when it got too high).
Accelerometers used in missiles also help correct for pitch orientation and keep the missiles on target. They are also used in model rocketry and in missile tests to determine the apogee, or the highest point the rocket reached before gravity pulls it back down.
Accelerometers are often used in fighter jets to determine how much pressure is being put on the pilots (how many “gees” they are pulling). The more gees, the pilot is pulling, the more difficult it can be to remain conscious. These accelerometers often alert pilots when they’re approaching this point.
- Calculating pitch and roll – How accelerometers help pilots make crucial calculations.
- Accelerometers verses Gyroscopes – How the two are different.
- Accelerometers in Aircraft – How they’re built and their uses.
- A PIGA accelerometer – A special type of accelerometer that’s often used in missiles.
- Trends in Accelerometer Design for Military and Aerospace Applications – An article from Sensor Magazine.
Fall Detection Devices
Accelerometers have many more uses than just in aircraft, of course. They’re used in the home every day in a number of ways and have medical applications. Accelerometers may help save the lives of those who are elderly or who have difficulty standing. These sensitive accelerometers are used in different fall detection devices. They sense when someone has suddenly fallen by determining the change in their velocity and in the direction, they are moving. If the device determines that the values for these two variables fall into the danger category, it will automatically send afall alertand call for help
What about slow falls? The accelerometer is useful here, too. These senior citizen fall detection devices can actually look at things like how smooth the acceleration is. This helps determine if the person has made a non-linear fall.
If someone falls in their home and is unable to call for help or has lost consciousness, their life could be at risk. Devices like emergency call buttons can help, but if the person is unconscious, they can’t make use of the device. A fall detection device doesn’t require the wearer to do anything—it automatically calls for help if it detects the person has fallen. The fall detection pendant’s sensor can sense falls in as little as two feet, which is important if your loved ones fall off a couch or bed. It is also important to note that automatic fall detection technology does not trigger with sliding movements and that is largely why they are not 100% accurate. Not all fall detection devices are created equal. Read our Medical Guardian reviews to compare.
- Evaluation of Accelerometer-based Fall Detection Algorithms – A scholarly paper on the subject.
- Detecting Human Falls – How 3-axis accelerometers are used.
- Wearable Sensors for Reliable Fall Detection – A Fall Detection Paper from U.C. Berkeley.
- Fall Detection – A Summary of Fall Detection from the University of Dundee, Scotland.
- Fall Detection Systems – Challenges, Issues, and Trends.
Tablet Computers and Cameras
Every smartphone, tablet, and digital camera produced in the last five years has an accelerometer in it. These devices have several uses. For example, most smartphones and tablets change how the screen is displayed when the phone or tablet is rotated. If the person is holding the device sideways, the information on the screen is displayed horizontally. Rotate the phone vertically, and the screen rotates, too. This is due to an accelerometer detecting the movement and motion of the device.
Accelerometers are also used in a number of apps and games. Racing games, for example, may allow players to control the steering of their car by turning the tablet or phone to one side. An accelerometer captures this movement and tells the game how to adjust the movement of the player’s vehicle.
In digital cameras, an accelerometer is used in much the same way: it tells the camera when it should take an image in landscape orientation and when it should use portrait. It also displays the pitch and roll of the camera’s axes, which helps to accurately display the image on the small screen.
- Accelerometers and Smartphones – How the device works in a smartphone.
- Motion Sensing in Clothing? – How smartphone accelerometers could be incorporated into clothing.
- Accelerometers and Device Identity – How accelerometers can be used to identify smartphones.
- Accelerometers – Their uses in different electronics by PC Magazine.
- What does the iPhone accelerometer do? – How the device works in an iPhone.
Conclusion
Smartphones, cameras, video game devices, airplanes, rockets, and fall detection devices are just a few of the many different things that use these tiny little devices. The medical applications alone make accelerometers one of the most important tools in day-to-day health and automatic fall detection. The early pioneers of this technology probably had no idea that it would go on to be something found in so many devices used on a daily basis. Perhaps future technology will make even more use out of this unique item.
It's fascinating to explore the depth and diversity of applications for accelerometers. These devices are truly omnipresent, embedded in various technologies and pivotal in several fields, from aviation to healthcare. Let's dive into the core concepts and related information mentioned in the article:
Accelerometer Functionality:
- Contrary to popular belief, accelerometers measure proper acceleration, which refers to an object's acceleration relative to inertia or free-fall, not just an increase in speed.
- When placed on the ground, an accelerometer detects the Earth's gravitational pull, showcasing a measurement due to this force acting upon it.
History and Types of Accelerometers:
- The first accelerometer sensor dates back to 1923, initially a resistance-bridge-type device, later commercialized by Southwark in the U.S.
- Over the years, various types emerged: two-axis, strain gage, Rochelle salt crystal, Barium Titanate, and the prevalent three-axis accelerometers used in smartphones, tablets, gaming consoles, and medical alert devices.
Applications in Aviation and Missiles:
- In aircraft, accelerometers determine pitch orientation, vital for maintaining flight within the Earth's curvature. They're also crucial in missiles for maintaining trajectory and determining apogee.
- In fighter jets, accelerometers monitor the G-forces pilots endure, helping prevent excessive stress that could lead to loss of consciousness.
Medical Applications—Fall Detection Devices:
- Accelerometers play a life-saving role in fall detection devices for the elderly or those with mobility issues.
- They sense sudden falls by analyzing changes in velocity and direction, automatically alerting for assistance.
Usage in Consumer Electronics:
- Accelerometers are integral in smartphones, tablets, and digital cameras, facilitating screen orientation changes and enabling motion-controlled apps and games.
Future Prospects:
- The applications of accelerometers continue to expand, shaping technological advancements across various industries.
The development and diverse applications of accelerometers underscore their profound impact on modern technology and daily life, from enhancing gaming experiences to potentially saving lives through automatic fall detection. These devices, initially conceived as measurement tools, have evolved into indispensable components across a multitude of industries. Their future holds the promise of even greater integration and innovation.