 |
| Place of Origin: | China (Mainland) |
| Brand Name: | Kacise |
| Certification: | certificate of explosion-proof, CE |
| Model Number: | KS3ARGA1 |
| Minimum Order Quantity: | 1pcs |
|---|---|
| Packaging Details: | each unit has individual box and all boxes are packed in standard packages or customers requests available |
| Delivery Time: | 5-8 working days |
| Payment Terms: | T/T, Western Union, MoneyGram |
| Supply Ability: | 1000 Pieces per Week |
| Operating Temperature Range: | -45~+80(°C) | Incoming CurrentmA: | <30 MA |
|---|---|---|---|
| Weight: | ≤40(g) | G-value Sensitivity: | <0.02(°/s/g) |
| Cross Coupling: | ≤2(%) | Offset Voltage: | 2.5±0.05(V) |
| Tolerated Acceleration: | 20000(0.1ms)(g) | Output Noise: | <0.02(°/s√Hz) |
The KS3ARGA1 series three-axis universal angular rate gyro is a sophisticated sensor crafted by Kacise to measure angular velocity across three axes. Incorporating state-of-the-art MEMS technology chips , each axis of this gyroscopic sensor showcases remarkable performance and reliability. It stands out for its cost-effectiveness, rugged packaging, and an intuitive self-test feature.
The functioning of the KS3ARGA1 series is grounded in the principles of the resonator gyro. It encompasses two polysilicon sensitive structures , each fitted with a high-frequency vibrating frame. These frames, which are electrostatically driven to resonate, are the crux of the gyro's operational mechanism. The outward ends of the frame are designed to form a capacitive sensing structure that responds to Coriolis forces encountered during angular motion. This reaction produces an electrical signal; after undergoing amplification and modulation stages, a final signal is outputted that corresponds directly with the angular rate.
● low power consumption
● wide operating temperature range
● wide bandwidth
● small size
● DC input DC output
● fast start
● high performance, low cost
Dimensions
| Parameter | KS3ARGA1 |
| Power supply parameter | |
| Input voltage | 6-15V(Vdc) |
| Incoming currentmA | <30 mA |
| Offset voltage | 2.5±0.05(V) |
| Output voltage | 0.5-4.5(V) |
| Product performance | |
| Range | ±250(°/s) |
| Scaling factor | 8±0.5(mv/°/s) |
| Nonlinearity | ≤0.05(%FR) |
| Resolution/Threshold | ≤0.1(°/s) |
| Cross coupling | ≤2(%) |
| Output noise | <0.02(°/s√Hz) |
| run-up time | ≤20(ms) |
| Bandwidth can customize | 80(Hz) |
| G-value sensitivity | <0.02(°/s/g) |
| Mean time between failures | 100000hour(MTBF) |
| Size | 34×25×24(mm) |
| Weight | ≤40(g) |
| Environment | |
| Operating temperature range | -45~+80(°C) |
| Storage temperature | -65~+125(°C) |
| Tolerated acceleration | 20000(0.1ms)(g) |
In the realm of automotive electronics , advancements have been monumental, leading to more sophisticated and seamless driving experiences. Innovations in this sector are central to the evolution of vehicles, paving the way for enhanced safety, efficiency, and overall user experience. As cars become increasingly automated, the role of cutting-edge electronics continues to expand, ensuring vehicles are smarter, more responsive, and adaptable to the needs of the modern driver.
The field of aviation has seen significant improvements, particularly within aircraft guidance and control systems . These improvements are critical to the safety and reliability of both commercial and military aircraft. By utilizing state-of-the-art sensors and computing technology, pilots are able to navigate with greater precision and ease, even under challenging conditions. Such advances in guidance systems have been instrumental in pushing the boundaries of what is possible in modern aeronautics.
Another area where technology has made a profound impact is in the development of attitude reference systems . These systems are designed to provide accurate orientation information, which is crucial in various applications from aerospace to marine navigation. Attitude reference systems have become more reliable and robust, resulting in improved operational capabilities for vehicles and vessels across diverse environments.
Furthermore, platform stabilization has seen enhancements that enable platforms to maintain a steady position despite external movements or forces. This is particularly important in platforms that require high precision, such as those used in measurement or observation. The ability to minimize or eliminate unwanted motion translates to better performance and increased accuracy in critical applications.
When it comes to robotics and communication, robot and antenna stabilization technologies play a pivotal role. The ability to maintain precision and control over movement is fundamental to the function of robots, while for antennas, it ensures clear and uninterrupted signal reception and transmission. These systems rely on advanced algorithms and mechanical design to achieve their high levels of stability and responsiveness.
Lastly, in the world of photography and videography, the evolution of stabilization technology has been a game-changer. The introduction of gyroscopes in cameras and digital camera technology has revolutionized the way we capture images. Whether in professional-grade cameras or smartphones, these gyros help to counteract hand-shake and motion blur, enabling users to capture sharp, high-quality images even in motion-intensive scenarios.
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 troubleshooting 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.
Packing and Shipping:
The Electronic Gyroscope Sensor is housed in a robust, anti-static packaging to ensure the device remains secure and undamaged during transit. The interior of the packaging is lined with a cushioning material that absorbs shocks and vibrations, providing additional protection for the sensitive components of the sensor.
Prior to shipment, each package is sealed and subjected to a thorough inspection to guarantee that the sensor is securely enclosed. The exterior of the packaging is clearly labeled with handling instructions and the package contents to facilitate careful handling and to inform the recipient about the enclosed device.
For shipping, the packaged Electronic Gyroscope Sensor is placed in a larger, durable cardboard box designed to withstand the rigors of transport. This box is further secured with packing tape and, if necessary, additional cushioning materials are added to prevent movement within the box during shipment.
Each shipment includes a detailed packing slip with product information and a unique serial number for inventory tracking and quality control purposes. The package is then dispatched through a reliable courier service with options for tracking and insurance to ensure the Electronic Gyroscope Sensor arrives at its destination promptly and in pristine condition.
Contact Person: Ms. Evelyn Wang
Tel: +86 17719566736
Fax: 86--17719566736
Address: i City, No11, TangYan South road, Yanta District, Xi'an,Shaanxi,China.
Factory Address:i City, No11, TangYan South road, Yanta District, Xi'an,Shaanxi,China.
