DS1822 | GUILCOR SENSORS

DS1822
Temperature sensors

High-precision digital temperature sensor with long-term stability, suitable for electronics and environmental monitoring.

Maximum precision
+/- 2,0°K

Minimum temperature
-55°C

Maximum temperature
+125°C

Minimum dimensions
4 x 6 x 27

Response time
Medium

Self-heating
Medium

Price
Low

Drift
Low

What is a DS1822 sensor ?

The DS1822 is a digital temperature sensor with a 1-Wire protocol, developed by Maxim Integrated as a cost-effective version of the DS18B20.

It maintains the same pinout, commands, and internal architecture, but with a wider tolerance and simplified calibration.

It is an excellent compromise between cost, reliability, and ease of integration, especially for consumer applications or non-critical sensor networks.

Operating principle

The DS1822 operates on the same principle as the DS18B20:

the measured temperature is converted to a digital format and transmitted via the 1-Wire bus.

The relationship remains:

T = Brut Value / 16

Each unit of measurement depends on the configured resolution (9 to 12 bits).

Resolution	Pass (°C)	Conversion time
9 bits	0,5 °C	93,75 ms
10 bits	0,25 °C	187,5 ms
11 bits	0,125 °C	375 ms
12 bits	0,0625 °C	750 ms

Technical specifications

Parameter	Typical Value
Measurement range	−55 °C → +125 °C
Typical precision	±2,0 K (−10 → +85 °C)
Resolution	9 to 12 bits (configurable)
Conversion time	93,75 to 750 ms
Alimentation	3.0 → 5.5 V or parasitic mode
Interface	Digital (1-Wire bus)
Unique identifier	64 bits (family 0x22)
Typical current	< 1 mA
Annual drift	Average (±0.5 K/year)
Case	TO-92, stainless steel cable or IP68 sealing

Wiring configuration

Type	Description	Precision
3-wires	VDD + DATA + GND	✅ Standard
2-wires (parasite)	DATA + GND, without dedicated power supply	💡 Wiring economy
Chained (multi-drop)	Multiple sensors on the same bus	🏗️ Wide Area Networks

Self-heating

Low (≈ 0.3 °C at 5 V).

Due to its low power consumption, the DS1822 is suitable for battery-operated systems or continuous measurements without significant thermal drift.

Application areas

⚙️ Economic Systems of Thermal Monitoring

🧱 Domestic and HVAC Applications

💧 Waterproof Thermometers for Pools, Aquariums, Greenhouses

🔋 Measurements on Microcontrollers (Arduino, ESP32, etc.)

🧠 Low-Cost Educational or IoT Projects

Should I choose a DS1822 sensor ?

Strengths points

💸 Excellent value for money
→ The DS1822 offers the same functions as the DS18B20 (12-bit resolution, 1-Wire bus, unique ID), but at a lower cost, perfect for high-volume projects.
🔗 Total compatibility with the DS18B20
→ Same pinout, same commands, and identical protocol: it can directly replace a DS18B20 without software modification.
🧠 Low consumption and parasitic mode
→ Ideal for low energy or battery-powered applications, with a simplified 2-wire power supply.

Weaknesses points

🎯 Reduced precision
→ With a typical tolerance of ±2 K, it is less accurate than the DS18B20 (±0.5 K). It is not well-suited for demanding industrial measurements.
📉 Average drift over time
→ The simplified calibration results in a drift of approximately ±0.5 K/year, requiring occasional recalibration during extended use.
📊 Not guaranteed across the entire extended range
→ Errors can increase beyond +85 °C or below -10 °C to be avoided for extreme environments.

Useful information

Here is some useful information regarding the DS1822 sensors.

Resolution and precision

The DS1822 has the same measurement core as the DS18B20, but with reduced accuracy and simplified calibration.

The resolution remains configurable from 9 to 12 bits, adjustable via the internal configuration register.

Resolution	No measurement (°C)	Conversion time	Accuracy (−10 → +85 °C)	Extended accuracy (−55 → +125 °C)
9 bits	0,5 °C	93,75 ms	±2,0 K	±3,0 K
10 bits	0,25 °C	187,5 ms	±2,0 K	±3,0 K
11 bits	0,125 °C	375 ms	±1,5 K	±2,5 K
12 bits	0,0625 °C	750 ms	±1,5 K	±2,0 K

🔹 Remarks:

Resolution and protocol identical to the DS18B20 → completely interchangeable.
Average annual drift (≈ ±0.5 K/year), stable for non-critical applications.
No recalibration required in most use cases.

Application example – Reading equation of a DS1822

As with the DS18B20, the DS1822 provides a 16-bit numeric value corresponding to the measured temperature.

The conversion formula is the same:

T(°C) = Brut Value / 16

🔹 Example 1 – Standard Reading

The sensor returns:

LSB = 0xA2
MSB = 0x00

Raw value 0x00A2 = 162₁₀ T = 162 / 16 = 10.125 °C

✅ Result: the measured temperature is ≈ 10.1 °C.

🔹 Example 2 – Negative reading

The sensor returns:

LSB = 0x5E
MSB = 0xFF

Raw value (two's complement):

Raw value 0xFF5E = -162₁₀ T = -162 / 16 = -10.125 °C

✅ Result: measured temperature = −10.1 °C.

🔹 Practical notes:

Reading via “Read Scratchpad” command (0xBE).
Resolution configured in the R1/R0 bits register.
The data includes TH/TL alarms and the CRC for validation.

Integration diagram in an electronic system

The DS1822 connects via a 1-Wire bus, similar to the DS18B20.

It operates in both normal mode (3 wires) and parasite mode (2 wires).

🔹 Typical components

Component	Function
DS1822	1-Wire Digital Sensor
Pull resistance 4.7 kΩ	Maintaining the DATA bus in a high state
Microcontroller (Arduino, ESP32, STM32, Raspberry Pi)	Bus Master
Shielded cable	Recommended beyond 10–15 m
Nutrition 3,3 V / 5 V	Source (or parasitic power)