Product Description:
KQRS14 Inertial Sensor
The KQRS14 is a compact and rugged solid-state inertial sensor that is primarily used to measure angular rotation rates. It is equipped with a monolithic quartz sensing element that ensures high accuracy and reliability in various applications. With its internal power regulation and DC input/high-level DC output operation, this sensor offers easy and convenient use.
There are two versions of the KQRS14 available in the market to cater to different needs. The first one is the +12Vdc version, which comes with a high-level +1.0 to +4.0 Vdc output. It is designed to operate from standard battery power, thereby making it an ideal choice for portable systems. The second version is the plus and minus15 Vdc version, which provides a high-level bipolar output of ±5 Vdc. This version is specifically designed for use with conventional double-sided power supplies.
Features:
● Compact,Lightweight Design
● Wide Temperature Range
● DC Input/High-Level DC Output
● lnternal Power Regulation
● High Reliability
● Shock Resistant
Technical Parameters:
| Parameter | KQRS14-0XXXX-102** | KQRS14-0XXXX-103** |
| Power Requirements |
| Input Voltage | +9 to +18 Vdc | +9 to +18 Vdc |
| Input Current | <20 mA | <25 mA (each supply) |
| Performance |
| Standard Ranges | ±50,100,200,500°/sec. |
| Full Scale Output (Nominal) | +1.0 Vdc (-FS) to +4.0 Vdc (+FS) | ±5 Vdc |
| Scale Factor Calibration (at 22°C Typical) | ±2% of value |
| Scale Factor Over Temperature (Dev. from 22°C Typical) | ≤0.06%/°C |
| Bias Calibration (at 22°C Typical) | +2.5 ±0.045 Vdc | 0.0±0.075 Vdc |
| Bias Variation over Temperature (Dev. from 22°C) | <3.0°/sec. |
| Short Term Bias Stability (100 sec at const. temp) | <0.05°/sec, typical |
| Long Term Bias Stability (1 year) | ≤1.0°/sec. |
| G Sensitivity (Typical) | ≤0.06°/sec/g |
| Start-Up Time (Typical) | <2.0 sec |
| Bandwidth (-90° Phase Shift) | >50 Hz |
| Non-Linearity (Typical) % Full Range | ≤0.05% of F.R. |
| Threshold/Resolution | ≤0.004°/sec.* |
| Output Noise (DC to 100 Hz) | ≤0.05°/sec./√Hz* | ≤0.02°/sec./√Hz* |
| Weight | ≤50 grams |
| Environments |
| Operating Temperature | -40°C to +85°C |
| Storage Temperature | -55°C to +100°C |
| Vibration Operating*** | 5 grms 20 Hz to 2 kHz random |
| Vibration Survival*** | 10 grms 20 Hz to 2 kHz random 5 minutes/axis |
| Shock | 200g,any axis |
Dimensions:
Description of the Interface:
KQRS14-0XXXX-102 pin assignment
| Num | Explain | Num | Explain |
| 1 | Power and Signal Ground | 5 | Rate Output |
| 2 | +Vdc Input | 6 | No connection, Leave Open |
| 3 | No connection, Leave Open | 7 | Built-in-test |
| 4 | No connection, Leave Open | | |
KQRS14-0XXXX-103 pin assignment
| Num | Explain | Num | Explain |
| 1 | -Vdc Input | 5 | Rate Output |
| 2 | +Vdc Input | 6 | No connection, Leave Open |
| 3 | Power Ground | 7 | Built-in-test |
| 4 | Signal Ground | | |
Applications:
Platform Stabilization:
One of the crucial technologies in today's world is platform stabilization which involves keeping a platform steady under varying environmental conditions. Platform stabilization technology is particularly important in the field of photography, videography, and military targeting systems where keeping the camera steady is essential for accurate shooting.
Short Term Navigation:
Short term navigation is the process of measuring a system's position and direction at small time intervals. This technology is essential in situations where high accuracy and fast response time are required such as aviation, maritime navigation, and exploration of unknown territories. Short term navigation systems can also be adapted for use in mobile phones, smart watches, and other wearable devices that require precise location tracking.
GPS Augmentation:
GPS augmentation is the process of enhancing the accuracy of global positioning systems (GPS) data. This technology is used in situations where high precision is required such as surveying, mapping, and scientific research. GPS augmentation can be accomplished through various means such as signal filtering, use of ground control stations, and integration with other sensors.
Camera Stabilization:
Camera stabilization is the process of reducing unwanted camera movements during shooting. This technology is crucial in the film and video industry where steady images are essential for quality content. Some common methods of camera stabilization include the use of gimbals, tripods, and steady-cams.
Instrumentation:
Instrumentation is the process of measuring and recording data using various sensors and devices. This technology is widely used in industries such as manufacturing, aerospace, and medical research. Instrumentation systems can help automate processes, detect faults, and monitor performance levels.
Ride Control Stabilization:
Ride control stabilization is the process of reducing vehicle oscillations during transit. This technology is critical for the safety and comfort of passengers during travel. Ride control stabilization technologies include the use of active and passive suspension systems, shock absorbers, and hydraulic and pneumatic dampeners.
Wind Turbine Control:
Wind turbine control is the process of regulating the output of wind turbines to ensure maximum power generation while minimizing maintenance costs. This technology involves monitoring wind conditions and turbine performance to optimize operational efficiency. Wind turbine control systems include pitch control mechanisms, active blade control, and condition monitoring systems.
Support and Services:
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 meticulously packaged in an anti-static bag to ensure protection against electrostatic discharge (ESD). The sensor is then securely encased in a custom-fit, high-density foam mold, which provides superior shock absorption during transit. This foam is placed within a durable, branded cardboard box that shields the sensor from environmental factors and potential damage while in transit.
The exterior of the box features clear labeling with the product name, handling instructions, and a barcode for easy tracking. All our packages are sealed with tamper-evident tape, offering an additional layer of security.
For shipping, the Electronic Gyroscope Sensor is dispatched via a trusted courier service to ensure timely and safe delivery. We include insurance for the full value of the product, offering peace of mind and protection for your investment. Tracking information is provided as soon as the package is dispatched, allowing for real-time monitoring of the shipment until it arrives at its destination.
