Datasheet — Zd10-100

For applications that require better resolution or the ability to drive a lower‑impedance load, you can add an operational amplifier in a non‑inverting configuration after the voltage divider. The official datasheet provides a reference circuit for this approach, which improves measurement resolution and provides a larger output current.

The fundamental physics governing the ZD10-100 sensor utilize the , which defines a precise inverse relationship between applied mechanical force and internal electrical path impedance.

| Parameter | Conditions | Min | Typ | Max | Unit | |-----------|------------|-----|-----|-----|------| | Zener Voltage (V Z ) | I ZT = 5 mA | 9.4 | 10 | 10.6 | V | | Reverse Leakage Current (I R ) | V R = 7.5V | - | - | 10 | µA | | Zener Impedance (Z ZT ) | I ZT = 5 mA | - | 30 | - | Ω | | Temperature Coefficient | I ZT = 5 mA | - | +0.07 | - | %/°C |

The data outlined below reflects standard operating parameters compiled from industrial component documentation. Specification Value Notes / Operating Conditions 0 to 500 g Optimized for low-mass/light touch profiles Thickness ≤is less than or equal to 0.25 mm to 0.30 mm Ultra-low profile component Response Point ≤is less than or equal to 20 g to 50 g Force threshold required to trigger transition Initial Resistance Open-circuit value with zero load applied Test Voltage 3.3 V DC (Typical) High compatibility with low-power MCUs Response Time Extremely rapid state transition Recovery Time Durability Lifecycle Actuations before performance degradation Operating Temperature -20°C to 60°C Rated for standard industrial environments EMI / ESD Sensitivity None / Insensitive Immune to high electromagnetic interference Mechanical Dimensions & Form Factor Go to product viewer dialog for this item. zd10-100 datasheet

As pressure increases, the resistance of the ZD10-100 decreases, causing the voltage at the Analog Pin to increase. 5.2 Calibration

Ultra-thin and flexible, allowing it to conform to curved surfaces like robotic fingers or wearable gear.

The ZD10-100 acts as a static non-loaded open circuit (>10MΩ). When mechanical stress overcomes its activation threshold, its core resistance falls precipitously into a measurable dynamic range spanning roughly several hundred ohms to tens of kilo-ohms. Mechanical & Physical Parameters For applications that require better resolution or the

< ±5% (at 50% fixed workload loading)

The is a highly sensitive, flexible thin-film pressure sensor (also known as a Force Sensing Resistor or FSR). It is designed to detect small pressure changes or bending movements, commonly used in smart home devices, medical electronics, and robotics. 1. Key Technical Specifications

The relationship is logarithmic. In the "sensitive" range, a small increase in force results in a large drop in resistance. 3. Implementation & Circuitry The is a highly sensitive, flexible thin-film pressure

Because microcontrollers cannot measure resistance directly, you must convert the changing resistance ( RSFcap R sub cap S cap F end-sub into a changing analog voltage ( VOUTcap V sub cap O cap U cap T end-sub ). This is achieved using a . Required Components ZD10-100 Sensor Fixed Resistor ( R1cap R sub 1

Here are some essential parameters extracted from the ZD10-100 datasheet:

The is a flexible, thin-film force-sensing resistor (FSR) designed for low-to-medium pressure detection . It is widely used in applications requiring tactile feedback, such as smart shelves, medical monitoring, and robotics. Key Technical Specifications

Wire a stationary pull-down resistor (such as a standard 10k Ωcap omega Ωcap omega

Understanding the ZD10-100 Datasheet: A Comprehensive Guide