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| Brand Name : | Kacise |
| Model Number : | KQ3GY |
| Certification : | certificate of explosion-proof, CE |
| Delivery Time : | 5-8 working days |
| Payment Terms : | T/T,Western Union,MoneyGram |
| Supply Ability : | 1000 Pieces per Week |
The KQ3GY gyroscope has been developed using Quartz MEMS
technology. Utilizing this technology ensures that multiple angular
velocities can be sensed simultaneously across multiple axes that
have been configured according to customer needs. Digital
information can be output through the serial port allowing for ease
of use.
MEMS technology has given rise to the development of micro-devices
and systems that integrate micro-components such as sensors,
actuators, mechanical structures, power, energy, signal processing
and control circuits. These high-performance electronic devices,
integrated with interfaces and communication systems, allow for the
creation of independent intelligent systems that can be
mass-produced. The overall size of these systems can be as small as
a few millimeters, and their internal structure is generally in the
order of microns and even nanometers.
The MEMS family of sensors encompasses a wide range of products
including accelerometers, optical sensors, pressure sensors,
gyroscopes, humidity sensors, gas sensors along with integration
products. All these MEMS products bring flexibility and precision
to various fields ranging from consumer electronics to industrial
applications.
| Parameter | KQ3Gy |
| Power Requirements | |
| Input Voltage | 5±0.2 Vdc |
| Input Current | < 50 mA |
| Performance | |
| Measurement range | ±100 |
| Bias | ≤0.03 |
| Bias stability | ≤20 |
| Bias repeatability | ≤20 |
| Scale factor nonlinearity | ≤200 |
| random walk | ≤0.25 |
| Threshold | ≤0.005 |
| Bandwidth | ≥140 |
| Acceleration correlation | ≤0.01 |
| Cross coupling | ≤1 |
| Environments | |
| Working temperature | -40℃~+65℃ |
| Random vibration | 6.06g rms |
Dimensions:
Unit:mm
Improving Aviation Technology
One important aspect of improving aviation technology is through
airborne instrument measurement. This involves the use of various
instruments that are mounted on aircraft to collect data on the
surrounding air, such as temperature, pressure, humidity, and wind
speed. This data is then used to improve aircraft designs and
performance.
Another technology that has contributed to the advancement of
aviation is the use of robots. Robots can be used in various ways
in the aviation industry, such as performing aircraft inspections
and maintenance. This technology allows for more efficient and
accurate inspections, reducing the risk of human error and
increasing safety.
Automated testing is another area where technology is improving
aviation. By using automated testing, aircraft components and
systems can be tested more efficiently and reliably, reducing the
risk of failures and errors during flights. This improves the
safety and reliability of aircraft.
The attitude reference system is a technology that helps aircraft
maintain their orientation in the air. This system uses sensors to
detect an aircraft's pitch, roll, and yaw, and provides information
to the control system to adjust the aircraft's attitude. This
technology is crucial for safe and stable flight.
The control system is another important technology in aviation. It
is responsible for controlling the aircraft's speed, altitude, and
direction of flight. With advances in technology, control systems
have become more sophisticated and efficient, allowing for safer
and more precise flight.
Flight testing is a crucial part of aviation technology
development, as it allows engineers to evaluate the performance of
aircraft designs in real-world conditions. During flight tests,
various instruments and sensors are used to gather data on the
aircraft's performance, which is then used to optimize and improve
the aircraft.
Finally, platform stability is another important aspect of aviation
technology. Stability in aircraft platforms is crucial for safe and
comfortable flight. Various technologies, such as wing and fuselage
design, are used to improve platform stability and control.
Our Electronic Gyroscope Sensor is designed with precision to
provide reliable performance for your applications. Our support
includes detailed product documentation, an extensive online
knowledge base, and trouble guides to help you resolve any issues
you may encounter.
We are committed to the satisfaction of our customers and strive to
provide exceptional after-sales support. Should you have any
feedback or suggestions, we welcome your input as it helps us to
continuously improve our products and services.
Product Packaging:
The Electronic Gyroscope Sensor product will be packaged in a
sturdy cardboard box with foam inserts to ensure safe transport.
The product will be sealed in a plastic bag to protect it from
moisture and dust. The box will be labeled with the product name,
brand, and barcode for easy identification.
Shipping:
The product will be shipped via standard ground shipping. We will
ensure that the product is shipped within 2 business days after
receiving the order. The shipping cost will be calculated based on
the weight and destination of the package. Customers will receive a
tracking number via email once the product has been shipped.
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