Digital sensors offer superior accuracy compared to analog sensors, ensuring precise measurements.
Noise Resistance
They are less susceptible to electromagnetic interference, providing more reliable data.
Ease of Integration
Digital sensors can easily integrate with digital systems and networks, facilitating advanced data analysis and automation.
Calibration Stability
They maintain calibration over longer periods, reducing the need for frequent recalibration.
Enhanced Diagnostics
Digital sensors come with self-diagnostic features, allowing for easier troubleshooting and maintenance
Data Transmission
They enable efficient and accurate data transmission over long distances without signal degradation.
Versatility
Digital sensors can be programmed for multiple functions, making them adaptable to various applications.
Reduced Wiring Complexity
Fewer wires are required for digital signals, simplifying installation and reducing potential points of failure.
Smart Features
They often include smart features such as auto-zeroing, temperature compensation, and dynamic filtering, enhancing overall performance.
Scalability
Digital sensor systems can be easily expanded with additional sensors and components, offering scalability for growing needs.
Digital Compensation and Filtering Technology
Traditional Digital Compensation and Filtering Technology
Microtess Digital Compensation and Filtering Technology
Digital Angle Deviation Adjustment Technology
Traditional analog sensors require professionals to continuously adjust the resistors inside the junction box to achieve angle deviation adjustment for the weighing platform.
Digital sensors, on the other hand, only need to load weights in sequence at the four corners of the weighing platform as prompted by the instrument to complete the angle deviation adjustment.
Compared to analog sensors, digital sensors make angle deviation adjustment more convenient and quicker.
Miniaturized Circuit and Design
Innovative miniaturized designs in structure and circuitry have overcome various limitations, such as how to achieve circuit design in very small spaces and how to design elastic sensitive areas.
Small-sized, high-capacity sensors are easier to integrate into various weighing applications and are highly welcomed by the market.
The digital sensor has the same dimensions as the analog sensor, allowing for direct replacement.
Digital Diagnostic Technology
When there is partial damage to the bridge circuit, the weight data will be output normally but will be inaccurate.
If the operator does not notice this and continues weighing, it can lead to losses.
Uninterrupted Operation During Node Failure
When a sensor in the system, such as LC4, fails, the diagnostic system can quickly display the location of the damaged sensor, making it convenient for maintenance personnel to replace it.
At the same time, the system can estimate the weight output of the failed sensor based on the functional relationship between the failed sensor and the surrounding sensors: \( W = f(W_1, W_2, W_3) \). This allows the weighing system to continue operating without interruption, and the damaged sensor can be replaced when the production system permits a shutdown.
Topology Network Structure Design
Traditional Star Network Topology
MICROTESS Chain Network Topology
No need for junction boxes and excessive cabling, reducing costs: Physical connections are simpler, reducing labor.
Anti-Cheating Secure Measurement Design
The specific data transmission encryption technology developed by Microtess can effectively prevent measurement fraud.
Distributed Intelligent Secure System Applications
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