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VL53L0X Time-of-Flight Distance Sensor Carrier with Voltage Regulator, 200cm Max

Prezzo originale €21,89 - Prezzo originale €21,89
Prezzo originale
€21,89
€21,89 - €21,89
Prezzo attuale €21,89

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This sensor is a carrier/breakout board for ST’s VL53L0X laser-ranging sensor, which measures the range to a target object up to 2 m away. The VL53L0X uses time-of-flight measurements of infrared pulses for ranging, allowing it to give accurate results independent of the target’s color and surface. Distance measurements can be read through a digital I²C interface. The board has a 2.8 V linear regulator and integrated level-shifters that allow it to work over an input voltage range of 2.6 V to 5.5 V, and the 0.1″ pin spacing makes it easy to use with standard solderless breadboards and 0.1″ perfboards.


Overview

The VL53L0X from ST Microelectronics is a time-of-flight ranging system integrated into a compact module. This board is a carrier for the VL53L0X, so we recommend careful reading of the VL53L0X datasheet (1MB pdf) before using this product.

The VL53L0 uses ST’s FlightSense technology to precisely measure how long it takes for emitted pulses of infrared laser light to reach the nearest object and be reflected back to a detector, so it can be considered a tiny, self-contained lidar system. This time-of-flight (TOF) measurement enables it to accurately determine the absolute distance to a target without the object’s reflectance greatly influencing the measurement. The sensor can report distances of up to 2 m (6.6 ft) with 1 mm resolution, but its effective range and accuracy (noise) depend heavily on ambient conditions and target characteristics like reflectance and size, as well as the sensor configuration. (The sensor’s accuracy is specified to range from ±3% at best to over ±10% in less optimal conditions.)

Ranging measurements are available through the sensor’s I²C (TWI) interface, which is also used to configure sensor settings, and the sensor provides two additional pins: a shutdown input and an interrupt output.

The VL53L0X is a great IC, but its small, leadless, LGA package makes it difficult for the typical student or hobbyist to use. It also operates at a recommended voltage of 2.8 V, which can make interfacing difficult for microcontrollers operating at 3.3 V or 5 V. Our breakout board addresses these issues, making it easier to get started using the sensor, while keeping the overall size as small as possible.

The carrier board includes a low-dropout linear voltage regulator that provides the 2.8 V required by the VL53L0X, which allows the sensor to be powered from a 2.6 V to 5.5 V supply. The regulator output is available on the VDD pin and can supply around 100 mA to external devices. The breakout board also includes a circuit that shifts the I²C clock and data lines to the same logic voltage level as the supplied VIN, making it simple to interface the board with 3.3 V or 5 V systems, and the board’s 0.1″ pin spacing makes it easy to use with standard solderless breadboards and 0.1″ perfboards. The board ships fully populated with its SMD components, including the VL53L0X, as shown in the product picture.

Alternative versions

The VL53L0X, VL53L1X, and VL53L3CX carriers all use the same PCB (labeled irs11a) and look similar (especially the VL53L0X and VL53L3CX carriers):

VL53L0X Time-of-Flight Distance Sensor Carrier.

VL53L1X Time-of-Flight Distance Sensor Carrier.

VL53L3CX Time-of-Flight Distance Sensor Carrier.

You can refer to the pictures above to help differentiate them, and you might also consider marking your boards if you have multiple types of these sensors.

For other similar sensors, see the comparison section at the bottom of this page.

VL53L0X datasheet graph of typical ranging performance (in default mode).

Specifications

  • Dimensions: 0.5″ × 0.7″ × 0.085″ (13 mm × 18 mm × 2 mm)
  • Weight without header pins: 0.5 g (0.02 oz)
  • Operating voltage: 2.6 V to 5.5 V
  • Supply current: 10 mA (typical average during active ranging)
    • Varies with configuration, target, and environment. Peak current can reach 40 mA.
  • Output format (I²C): 16-bit distance reading (in millimeters)
  • Distance measuring range: up to 2 m (6.6 ft); see the graph at the right for typical ranging performance.
    • Effective range depends on configuration, target, and environment.
    • The datasheet does not specify a minimum range, but in our experience, the effective limit is about 3 cm.

Included components

A 1×7 strip of 0.1″ header pins and a 1×7 strip of 0.1″ right-angle header pins are included, as shown in the picture below. You can solder the header strip of your choice to the board for use with custom cables or solderless breadboards, or you can solder wires directly to the board itself for more compact installations.

VL53L0X Time-of-Flight Distance Sensor Carrier with included header pins.

VL53L0X Time-of-Flight Distance Sensor Carrier in a breadboard.

The board has two mounting holes spaced 0.5″ apart that work with #2 and M2 screws (not included).

Using the VL53L0X

Important note: This product might ship with a protective liner covering the sensor IC. The liner must be removed for proper sensing performance.

Connections

At least four connections are necessary to use the VL53L0X board: VIN, GND, SCL, and SDA. The VIN pin should be connected to a 2.8 V to 5.5 V source, and GND should be connected to 0 volts. An on-board linear voltage regulator converts VIN to a 2.8 V supply, which can be accessed via the VDD pin, for the VL53L0X IC. Supply voltages between 2.6 V and 3.5 V can also be connected to VDD (with VIN left disconnected) to bypass the regulator and power the board directly.

The I²C pins, SCL and SDA, are connected to built-in level-shifters that make them safe to use at voltages above VDD; they should be connected to an I²C bus operating at the same logic level as VIN (or VDD, if powering the board through VDD).

The XSHUT pin is an input and the GPIO1 pin is an open-drain output; both pins are pulled up to VDD by the board. They are not connected to level-shifters on the board and are not 5V-tolerant, but they are usable as-is with many 3.3 V and 5 V microcontrollers: the microcontroller can read the GPIO1 output as long as its logic high threshold is below VDD, and the microcontroller can alternate its own output between low and high-impedance states to drive the XSHUT pin. Alternatively, our 4-channel bidirectional logic level shifter can be used externally with those pins.

Pinout

PIN Description
VDD Regulated 2.8 V output. Up to around 100 mA is available to power external components. (If you want to bypass the internal regulator, you can instead use this pin as a 2.6 V to 3.5 V input with VIN disconnected.)
VIN This is the main 2.8 V to 5.5 V power supply connection. The SCL and SDA level shifters pull the I²C lines high to this level.
GND The ground (0 V) connection for your power supply. Your I²C control source must also share a common ground with this board.
SDA Level-shifted I²C data line: HIGH is VIN, LOW is 0 V
SCL Level-shifted I²C clock line: HIGH is VIN, LOW is 0 V
XSHUT This pin is an active-low shutdown input; the board pulls it up to VDD to enable the sensor by default. Driving this pin low puts the sensor into hardware standby. This input is not level-shifted.
GPIO1 Programmable interrupt output (VDD logic level). This output is not level-shifted.

Schematic diagram

The above schematic shows the additional components the carrier board incorporates to make the VL53L0 easier to use, including the voltage regulator that allows the board to be powered from a 2.6 V to 5.5 V supply and the level-shifter circuit that allows for I²C communication at the same logic voltage level as VIN. This schematic is also available as a downloadable PDF (108k pdf).

I²C communication

The VL53L0X can be configured and its distance readings can be queried through the I²C bus. Level shifters on the I²C clock (SCL) and data (SDA) lines enable I²C communication with microcontrollers operating at the same voltage as VIN (2.6 V to 5.5 V). A detailed explanation of the I²C interface on the VL53L0X can be found in its datasheet (1MB pdf), and more detailed information about I²C in general can be found in NXP’s I²C-bus specification (1MB pdf).

The sensor’s 7-bit slave address defaults to 0101001b on power-up. It can be changed to any other value by writing one of the device configuration registers, but the new address only applies until the sensor is reset or powered off. ST provides an application note (196k pdf) that describes how to use multiple VL53L0X sensors on the same I²C bus by individually bringing each sensor out of reset and assigning it a unique address.

The I²C interface on the VL53L0X is compliant with the I²C fast mode (400 kHz) standard. In our tests of the board, we were able to communicate with the chip at clock frequencies up to 400 kHz; higher frequencies might work but were not tested.

Sensor configuration and control

In contrast with the information available for many other devices, ST has not publicly released a register map and descriptions or other documentation about configuring and controlling the VL53L0X. Instead, communication with the sensor is intended to be done through ST’s VL53L0X API (STSW-IMG005), a set of C functions that take care of the low-level interfacing. To use the VL53L0X, you can customize the API to run on a host platform of your choice using the information in the API documentation. Alternatively, it is possible to use the API source code as a guide for your own implementation.

Sample Code

We have written a basic Arduino library for the VL53L0X, which can be used as an alternative to ST’s official API for interfacing this sensor with an Arduino or Arduino-compatible controller. The library makes it simple to configure the VL53L0X and read the distance data through I²C. It also includes example sketches that show you how to use the library.

Pololu’s family of carriers for ST time-of-flight distance sensors

We make pin-compatible carriers/breakout boards for several different ST time-of-flight (ToF) ranging sensors, as shown in the table below. They all function as tiny lidar systems featuring an integrated 940 nm Class 1 (i.e. invisible and eye-safe) laser, and they are all based on the same FlightSense technology, which precisely measures how long it takes for emitted pulses of infrared laser light to reach the objects and be reflected back to a detector. This approach ensures absolute distance measurements independent of ambient lighting conditions and target characteristics (e.g. color, shape, texture, and reflectivity), though these external conditions do affect the maximum range of the sensor. These sensors are all capable of 1 mm resolution, with some limitations on some versions.


VL6180X
carrier

VL53L0X
carrier

VL53L1X
carrier

VL53L3CX
carrier

VL53L5CX
carrier

VL53L7CX
carrier
Maximum range:(1) 60 cm 200 cm 400 cm 500 cm 400 cm 350 cm
Minimum range: ~1 cm ~3 cm 4 cm 1 cm 2 cm 2 cm
Field of view: 25° 25° 15° to 27° diagonal,
program­mable
25° 65° diagonal,
up to 8×8 zones
90° diagonal,
up to 8×8 zones
Other features: ambient light sensing,
low memory footprint(2)
low memory footprint(2) low memory footprint(2) multi-target detection multi-target detection multi-target detection
Maximum update rate:(1) ~150 Hz 50 Hz 100 Hz 125 Hz 60 Hz 60 Hz
Operating voltage range: 2.6 V to 5.5 V 2.5 V to 5.5 V
Regulator voltage: 2.8 V 3.3 V
Typical active-ranging
supply current:
25 mA 20 mA 20 mA 20 mA 100 mA 100 mA
Peak supply current: 40 mA 40 mA 40 mA 40 mA 150 mA 150 mA
1-piece price: $13.49 $14.95 $18.95 $16.95 $19.95 $19.95
1 Effective range and update rate depend on configuration, target, and environment.
2 Suitable for use with typical 8-bit MCUs.

These carriers all have the same physical dimensions (0.5″ × 0.7″) and work in 3.3 – 5 V systems (thanks to their integrated linear regulators and level-shifters), and they are all controlled through an I²C interface. However, they have different APIs and memory requirements, so software will generally need to be rewritten when switching between sensors in an application, and versions with higher memory requirements are generally not suitable for use with typical 8-bit microcontrollers.