A clinometer or inclinometer is an instrument for measuring angles of slope (or tilt), elevation or depression of an object with respect to gravity. It is also known as a tilt indicator, tilt sensor, tilt meter, slope alert, slope gauge, gradient meter, gradiometer, level gauge, level meter, declinometer, and pitch & roll indicator. Clinometers measure both inclines (positive slopes, as seen by an observer looking upwards) and declines (negative slopes, as seen by an observer looking downward) using three different units of measure: degrees, percent, and topo (see Grade (slope) for details). Astrolabes are inclinometers that were used for navigation and locating astronomical objects from ancient times to the Renaissance.
A tilt sensor can measure the tilting in often two axes of a reference plane in two axes. In contrast, a full motion would use at least three axes and often additional sensors. One way to measure tilt angle with reference to the earth's ground plane, is to use an accelerometer. Typical applications can be found in the industry and in game controllers. In aircraft, the "ball" in turn coordinators or turn and bank indicators is sometimes referred to as an inclinometer.
Inclinometers include examples such as Well's in-clinometer, the essential parts of which are a flat side, or base, on which it stands, and a hollow disk just half filled with some heavy liquid. The glass face of the disk is surrounded by a graduated scale that marks the angle at which the surface of the liquid stands, with reference to the flat base. The zero line is parallel to the base, and when the liquid stands on that line, the flat side is horizontal; the 90 degree is perpendicular to the base, and when the liquid stands on that line, the flat side is perpendicular or plumb. Intervening angles are marked, and, with the aid of simple conversion tables, the instrument indicates the rate of fall per set distance of horizontal measurement, and set distance of the sloping line.
The Abney level is a handheld surveying instrument developed in the 1870s that includes a sighting tube and inclinometer, arranged so that the surveyor may align the sighting tube (and its crosshair) with the reflection of the bubble in the spirit level of the inclinometer when the line of sight is at the angle set on the inclinometer.
One of the more famous inclinometer installations was on the panel of the Ryan NYP "The Spirit of St. Louis"—in 1927 Charles Lindbergh chose the lightweight Rieker Inc P-1057 Degree Inclinometer to give him climb and descent angle information.
Hand-held clinometers are used for a variety of surveying and measurement tasks. In land surveying and mapping, a clinometer can provide a rapid measurement of the slope of a geographic feature, or used for cave survey. In prospecting for minerals, clinometers are used to measure the strike and dip of geologic formations. In forestry, tree height measurement can be done with a clinometer using standardized methods. Major artillery guns may have an associated clinometer used to facilitate aiming of shells over long distances.
Permanently-installed tiltmeters are emplaced at major earthworks such as dams to monitor the long-term stability of the structure.
Factors which influence the use of inclinometers
(Overall accuracy varies depending on the type of tilt sensor (or inclinometer) and technology used)
- Temperature (drift), zero offset, linearity, vibration, shock, cross-axis sensitivity, acceleration/deceleration.
- A clear line of sight between the user and the measured point is needed.
- A well defined object is required to obtain the maximum precision.
- The angle measurement precision and accuracy is limited to slightly better than one arcsec.
- The calibration of tilt sensors in the factory may differ on the actual site.
Certain highly sensitive electronic inclinometer sensors can achieve an output resolution to 0.0001°; depending on the technology and angle range, it may be limited to 0.01°. An inclinometer sensor's true or absolute accuracy (which is the combined total error), however, is a combination of initial sets of sensor zero offset and sensitivity, sensor linearity, hysteresis, repeatability, and the temperature drifts of zero and sensitivity—electronic inclinometers accuracy can typically range from ±0.01–2° depending on the sensor and situation. Typically in room ambient conditions the accuracy is limited to the sensor linearity specification.
Tilt sensors and inclinometers generate an artificial horizon and measure angular tilt with respect to this horizon. They are used in cameras, aircraft flight controls, automobile security systems, and speciality switches and are also used for platform leveling, boom angle indication, and in other applications requiring measurement of tilt.
Important specifications to consider for tilt sensors and inclinometers are the tilt angle range and the number of axes. The axes are usually, but not always, orthogonal. The tilt angle range is the range of desired linear output.
Common implementations of tilt sensors and inclinometers are accelerometer, Liquid Capacitive, electrolytic, gas bubble in liquid, and pendulum.
Tilt sensor technology has also been implemented in video games. Yoshi's Universal Gravitation and Kirby Tilt 'n' Tumble are both built around a tilt sensor mechanism, which is built into the cartridge. The PlayStation 3 and Wii game controllers also use tilt as a means to play video games.
Inclinometers are also used in civil engineering, for example, to measure the inclination of land to be built upon.
Some inclinometers provide an electronic interface based on CAN (Controller Area Network). In addition, those inclinometers may support the standardized CANopen profile (CiA 410). In this case, these inclinometers are compatible and partly interchangeable.
Two-axis digital inclinometer
Traditional spirit levels and pendulum-based electronic leveling instruments are usually constrained by only single-axis and narrow tilt measurement range. However, most precision leveling, angle measurement, alignment and surface flatness profiling tasks essentially involve a two-dimensional surface plane angle rather than two independent orthogonal single-axis objects. Two-axis inclinometers that are built with MEMS tilt sensors provides simultaneous two-dimensional angle readings of a surface plane tangent to earth datum.
Typical advantages of using two-axis MEMS inclinometers over conventional single-axis "bubble" or mechanical leveling instruments may include:
- Simultaneous measurement of two-dimensional (X-Y plane) tilt angles (i.e. pitch & roll), can eliminate tedious swopping back-and-forth experienced when using a single-axis level, for example to adjust machine footings to attain a precise leveling position.
- Digital compensation and precise calibration for non-linearity, for example for operating temperature variation, resulting in higher accuracy over a wider measurement range.
- The accelerometer sensors may generate numerical data in the form of vibration profiles to enable a machine installer to track and assess alignment quality in real-time and verify a structure's positional stability by comparing leveling profiles before and after it is set up.
Inclinometer with gyroscope
As inclinometers measure the angle of an object with respect to the force of gravity, external accelerations like rapid motions, vibrations or shocks will introduce errors in the tilt measurements. To overcome this problem, it is possible to use a gyroscope in addition to an accelerometer. Any of the above mentioned accelerations have a huge impact on the accelerometer, but a limited effect on the measured rotation rates of the gyroscope. An algorithm can combine both signals to get the best value out of each sensor. This way it is possible to separate the actual tilt angle from the errors introduced by external accelerations.
Inclinometers are used for:
- Determining latitude using Polaris (in the Northern Hemisphere) or the two stars of the constellation Crux (in the Southern Hemisphere).
- Determining the angle of the Earth's magnetic field with respect to the horizontal plane.
- Showing a deviation from the true vertical or horizontal.
- Surveying, to measure an angle of inclination or elevation.
- Alerting an equipment operator that it may tip over.
- Measuring angles of elevation, slope, or incline, e.g. of an embankment.
- Measuring slight differences in slopes, particularly for geophysics. Such inclinometers are, for instance, used for monitoring volcanoes, or for measuring the depth and rate of landslide movement.
- Measuring movements in walls or the ground in civil engineering projects.
- Determining the dip of beds or strata, or the slope of an embankment or cutting; a kind of plumb level.
- Some automotive safety systems.
- Indicating pitch and roll of vehicles, nautical craft, and aircraft. See turn coordinator and slip indicator.
- Monitoring the boom angle of cranes and material handlers.
- Measuring the "look angle" of a satellite antenna towards a satellite.
- Adjusting a solar panel to the optimal angle to maximize its output.
- Measuring the slope angle of a tape or chain during distance measurement.
- Measuring the height of a building, tree, or other feature using a vertical angle and a distance (determined by taping or pacing), using trigonometry.
- Measuring the angle of drilling in well logging.
- Measuring the list of a ship in still water and the roll in rough water.
- Measuring steepness of a ski slope.
- Measuring the orientation of planes and lineations in rocks, in combination with a compass, in structural geology.
- Measuring range of motion in the joints of the body
- Measuring the inclination angle of the pelvis. Numerous neck and back measurements require the simultaneous use of two inclinometers.
- Measuring the angles of elevation to, and ultimately computing the altitudes of, many things otherwise inaccessible for direct measurement.
- Measuring and fine tuning the angle of line array speaker hangs. Confirmation of the angle achieved via use of a laser built into the remote inclinometer.
- Setting correct orientation of solar panels while installing
- Setting firing angle of a cannon or gun (determines projectile range)
- Electronic games
- Help prevent unsafe working conditions.
- The USDA Forest Service uses tilt sensors (or inclinometers) to measure tree height in its Forest Inventory and Analysis program.
Tilt indicators are disposable-grade, albeit reusable sensors attached to goods as part of packaging during shipping.
Nintendo used tilt sensor technology in five games for its Game Boy series of hand-held game systems. The tilt sensor allows players to control aspects of the game by twisting the game system. Games that use this feature:
- Yoshi's Universal Gravitation (Game Boy Advance)
- WarioWare: Twisted! (Game Boy Advance)(not released in Europe)
- Koro Koro Puzzle Happy Panechu! (Game Boy Advance)(Japan only)
- Kirby Tilt 'n' Tumble (Game Boy Color)(not released in Europe)
- Command Master (Game Boy Color)(Japan only)
However, unlike these other controllers in which the tilt sensor serves as a supplement to normal control methods, it serves as one of the central features of Nintendo's Wii Remote and the Nunchuk attachment. Along with accelerometers, the tilt sensors are a primary method of control in most Wii games.
It is now being used in many different aspects, instead of just games like motocrossing and flight simulators. It can be used for sport gaming, first-person shooter, and other odd uses such as in WarioWare: Smooth Moves
Another example is a virtual version of a wooden maze with obstacles in which you have to maneuver a ball by tilting the maze. A homebrew tilt sensor interface was made for the Palm (PDA).
- Rieker Inc P-1057 Degree Inclinometer
- POSITAL. "MEMS Inclinometer from POSITAL: How do they work?". Posital. Retrieved 2017-01-04.
- "Archived copy". Archived from the original on 2013-07-03. Retrieved 2013-07-19.
- "New Tilt Sensor Helps to Prevent Unsafe Working Conditions". www.frederickscompany.com. Archived from the original on 23 September 2016.
- "Tilt Indicators for Fragile Goods in Transport". Shockwatch. Retrieved 6 June 2011.
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