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 Si7051 
 Temperature sensors 

Precision digital temperature sensor with excellent stability and accuracy for industrial and embedded systems.

 Measurement range
-40 / 125°C

 Temperature accuracy
+/- 0,1°K

 Resolution (Rh and T°)
14 bits

 Power supply voltage
1,9 → 3,6V

Conversion time
10 ms

 Typical current
195µA(active)

 I²C Speed
100 / 400 kHz

 Price
Medium

What is a Si7051 sensor ?Operating principleVoltage / Temperature CurveOperating principlePrinciple diagram (I2C connection)Application areas

What is a Si7051 sensor ?

The Si7051 is a precision digital temperature sensor that uses the I²C bus to communicate directly with a microcontroller.

Based on patented CMOS technology, it offers exceptional long-term stability and laboratory-grade accuracy in a tiny form factor.

It is often used as a reference sensor in:

  • low-power IoT systems,
  • medical connected devices,
  • data loggers and calibration devices.

Operating principle

The sensor integrates:

  • an ultra-stable CMOS thermal detection element,
  • a 14-bit analog-to-digital converter,
  • and an internal processor that applies the calibration curve stored in EEPROM.

The temperature is calculated from a raw code (Tcode) according to the formula provided by Silicon Labs:

T(°C) = (175,72 × T_code) / 2¹⁶ − 46,85

💡 The calibration coefficients are factory integrated and guaranteed across the entire range.

Voltage / Temperature Curve

The Si7051 does not output an analog voltage, but we can visualize the equivalent digital curve:

T (°C) Binary code (on 16 bits)
−40 0x0000
0 0x3A70
+25 0x61A0
+85 0xC000
+125 0xF320

💡 The relationship is almost linear, ideal for digital processing without recalibration.

Operating principle

#include <Wire.h>
#define SI7051_ADDR 0x40
#define CMD_MEASURE_TEMP 0xF3

void setup() {
  Serial.begin(9600);
  Wire.begin();
}

void loop() {
  Wire.beginTransmission(SI7051_ADDR);
  Wire.write(CMD_MEASURE_TEMP);
  Wire.endTransmission();
  delay(15);
  Wire.requestFrom(SI7051_ADDR, 2);
  uint16_t raw = (Wire.read() << 8) | Wire.read();
  float tempC = ((175.72 * raw) / 65536.0) - 46.85;
  Serial.print("Température : ");
  Serial.print(tempC, 2);
  Serial.println(" °C");
  delay(1000);
}

✅ Example of result:

Temperature: 23.72 °C

Principle diagram (I2C connection)

+3.3V
 │
[Si7051]
 │ SDA ───────┐
 │ SCL ───────┤── MCU (Arduino, STM32, ESP32…)
 │ GND

💡 4.7 kΩ pull-up resistors recommended on SDA/SCL.

Application areas

🧠 Medical equipment and wearables

🏭 Precise industrial measurements

🧪 Instrumentation and calibration

🌿 IoT sensors and connected objects

🔋 Battery-powered systems



Should I choose a Si7051 sensor ?

Strengths points

  • 🎯 Deadly accuracy
         → ±0.1 K over the useful range – comparable to a Pt100 class A sensor.
  • 🔋 Ultra low power consumption→ Ideal for long-lasting battery devices.
  • 🧠 Factory calibration
         → No correction needed: ready to use.
  • ⚙️ Universal I²C Integration
         → Compatible with all modern microcontrollers.
Si7051 probes

Weaknesses points

  • 💰 Higher cost than consumer sensors
         → But justified by its metrological precision.
  • 🌡️ No humidity or pressure measurement
         → It is a purely thermal sensor.
  • 📏 Tiny package (DFN)
         → Requires good PCB routing or pre-assembled module.

Useful information

Here is some useful information regarding the Si7051 sensors.

Brooch
 Name
 Description
1 VDD 1,9–3,6 V
2 GND Mass
3 SDA I²C Data
4 SCL I²C Clock
💡 On breakout modules, pull-up resistors are often integrated.
Command (hex) Description
0xE3 Measure temperature (hold master)
0xF3 Measure temperature (no hold)
0xE0 Firmware reading
0xFE Sensor reset
0xFA 0x0F Reading of the electronic ID
3.3V ─────────┐
              │
             [Si7051]
              │ SDA ─────┐
              │ SCL ─────┤── MCU
              │ GND

💡 L’adresse I²C fixe (0x40) simplifie la configuration.

Température (°C) Erreur typique (K) Dérive annuelle
−40 ±0,2 < 0,02 K/an
0 ±0,1 < 0,02 K/an
+25 ±0,1 < 0,02 K/an
+85 ±0,15 < 0,02 K/an
+125 ±0,2 < 0,02 K/an

💡 Une stabilité à long terme exemplaire, sans recalibration.

La sortie est parfaitement linéaire entre −40 °C et +125 °C, ce qui permet d’obtenir :

T(code) = a · T_réelle + b

avec a≈1.000 et b≈0.0

💡 Aucune compensation nécessaire même après plusieurs années d’utilisation.

 We integrate any sensor into any probe 

Smooth tube probe

 Smooth tube 

Waterproof probe

 Waterproof

Bayonet probe

 Bayonet

Slot probe

 Slot

Ambient probe

 Atmosphere

Head connection probe

Termal block

Stick-in probe

Stick-in

Thread probe

Thread

Contact probe

Contact

Jacketed probe

Jacketed

PCBA Design

PCBA design

Winding probe

Winding

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