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/****************************************************************************
**
** Copyright (C) 2015 The Qt Company Ltd.
** Contact: http://www.qt.io/licensing/
**
** This file is part of the documentation of the Qt local connectivty modules.
**
** $QT_BEGIN_LICENSE:FDL$
** Commercial License Usage
** Licensees holding valid commercial Qt licenses may use this file in
** accordance with the commercial license agreement provided with the
** Software or, alternatively, in accordance with the terms contained in
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** information use the contact form at http://www.qt.io/contact-us.
**
** GNU Free Documentation License Usage
** Alternatively, this file may be used under the terms of the GNU Free
** Documentation License version 1.3 as published by the Free Software
** Foundation and appearing in the file included in the packaging of
** this file. Please review the following information to ensure
** the GNU Free Documentation License version 1.3 requirements
** will be met: http://www.gnu.org/copyleft/fdl.html.
** $QT_END_LICENSE$
**
****************************************************************************/
/*!
\ingroup technology-apis
\title Bluetooth Low Energy Overview
\page qtbluetooth-le-overview.html
\brief The Qt Bluetooth Low Energy API enables communication between Bluetooth
Low Energy devices.
\tableofcontents
\section1 Technology Preview
The Qt Bluetooth Low Energy API was introduced by Qt 5.4. Since Qt 5.5 the API
is frozen and a compatibility guarantee is given for future releases.
At the moment, Qt only supports the Bluetooth Low Energy central role.
For more details on this limitation see below.
\section1 What Is Bluetooth Low Energy
Bluetooth Low Energy, also known as Bluetooth Smart, is a wireless computer
network technology, which was officially introduced in 2011. It works on the same
2.4 GHz frequency as ”classic” Bluetooth. The main difference is, as stated by its technology name,
low energy consumption. It provides an opportunity for Bluetooth Low Energy devices to
operate for months, even years, on coin-cell batteries. The technology was introduced by
\l {https://www.bluetooth.org/en-us/specification/adopted-specifications}{Bluetooth v4.0}.
Devices which support this technology are called Bluetooth Smart Ready Devices.
The key features of the technology are:
\list
\li Ultra-low peak, average and idle mode power consumption
\li Ability to run for years on standard, coin-cell batteries
\li Low cost
\li Multi-vendor interoperability
\li Enhanced range
\endlist
Bluetooth Low Energy uses a client-server architecture. The server (also
known as peripheral) offers services such as temperature or heart rate
and advertises them. The client (known as central
device) connects to the server and reads the values advertised by the server.
An example might be an apartment with Bluetooth Smart Ready sensors such
as a thermostat, humidity or pressure sensor. Those sensors are peripheral
devices advertising the environment values of the apartment. At the same time
a mobile phone or computer might connect to those sensors, retrieve their
values and present them as part of a larger environment control application
to the user.
\section1 Basic Service Structure
Bluetooth Low Energy is based on two protocols: ATT (Attribute Protocol)
and GATT (Generic Attribute Profile). They specify the communication layers
used by every Bluetooth Smart Ready device.
\section2 ATT Protocol
The basic building block of ATT is an \e attribute. Each attribute consists of
three elements:
\list
\li a value - the payload or desirable piece of information
\li a UUID - the type of attribute (used by GATT)
\li a 16-bit handle - a unique identifier for the attribute
\endlist
The server stores the attributes and the client uses the ATT protocol to
read and write values on the server.
\section2 GATT Profile
GATT defines grouping for a set of attributes by applying a meaning to predefined
UUIDs. The table below shows an example service exposing a heart rate
on a particular day. The actual values are stored inside the two characteristics:
\table
\header
\li Handle
\li UUID
\li Value
\li Description
\row
\li 0x0001
\li 0x2800
\li UUID 0x180D
\li Begin Heart Rate service
\row
\li 0x0002
\li 0x2803
\li UUID 0x2A37, Value handle: 0x0003
\li Characteristic of type \e {Heart Rate Measurement (HRM)}
\row
\li 0x0003
\li 0x2A37
\li 65 bpm
\li Heart rate value
\row
\li 0x0004
\li 0x2803
\li UUID 0x2A08, Value handle: 0x0006
\li Characteristic of type Date Time
\row
\li 0x0005
\li 0x2A08
\li 18/08/2014 11:00
\li Date and Time of the measurement
\row
\li 0x0006
\li 0x2800
\li UUID xxxxxx
\li Begin next service
\row
\li ...
\li ...
\li ...
\li ...
\endtable
GATT specifies that the above used UUID \c 0x2800 marks the begin of a service definition.
Every attribute following \c 0x2800 is part of the service until the next \c 0x2800 or the
end is encountered. In similar ways the well known UUID \c 0x2803 states that a characteristic
is to be found and each of the characteristics has a type defining the nature of the value.
The example above uses the UUIDs \c 0x2A08 (Date Time) and \c 0x2A37 (Heart Rate Measurement).
Each of the above UUIDs is defined by the \l {https://bluetooth.org}{Bluetooth Special Interest Group}.
and can be found in the
\l{https://developer.bluetooth.org/gatt/Pages/default.aspx}{GATT specification}. While it
is advisable to use pre-defined UUIDs where available it is entirely possible to use new and not
yet used UUIDs for characteristic and service types.
In general, each service may consist of one or more characteristics. A characteristic
contains data and can be further described by descriptors, which provide additional
information or means of manipulating the characteristic. All services, characteristics and
descriptors are recognized by their 128-bit UUID. Finally, it is possible to include
services inside of services (see picture below).
\image peripheral-structure.png
\section1 Using Qt Bluetooth Low Energy API
This section describes how to use the Bluetooth Low Energy API provided by Qt. Currently the API
permits creating connections to peripheral devices, discovering their services, as well as reading
and writing data stored on the device. The example code below is taken from the
\l {heartlistener}{Heart Listener} example.
\note As of Qt 5.4 the Qt Bluetooth Low Energy API is in tech preview mode and supports Linux
with BlueZ 4.101 & 5.x. The minimal Linux kernel version is 3.5.
\section2 Establishing a Connection
To be able to read and write the characteristics of the Bluetooth Low Energy peripheral device,
it is necessary to find and connect the device. This requires the peripheral device to advertise
its presence and services. We start the device discovery with the help of the
\l QBluetoothDeviceDiscoveryAgent class. We connect to its \l {QBluetoothDeviceDiscoveryAgent::deviceDiscovered()}
signal and start the search with \l {QBluetoothDeviceDiscoveryAgent::start()}{start()}:
\snippet heartlistener/heartrate.cpp devicediscovery-1
\snippet heartlistener/heartrate.cpp devicediscovery-2
Since we are only interested in Low Energy devices we filter the device type within the
receiving slot. The device type can be ascertained using the \l QBluetoothDeviceInfo::coreConfigurations()
flag:
\snippet heartlistener/heartrate.cpp devicediscovery-3
\snippet heartlistener/heartrate.cpp devicediscovery-4
Once the address of the peripheral device is known we use the \l QLowEnergyController class.
This class is the entry point for all Bluetooth Low Energy development. The constructor of the class
accepts the remote device's \l QBluetoothAddress. Finally we set up the customary slots and
directly connect to the device using
\l {QLowEnergyController::connectToDevice()}{connectToDevice()}:
\snippet heartlistener/heartrate.cpp Connect signals
\section2 Service Search
As soon as the connection is established we initiate the service discovery:
\snippet heartlistener/heartrate.cpp Connecting to service
The \c serviceDiscovered() slot below is triggered as a result of the
\l {QLowEnergyController::serviceDiscovered()} signal and provides an intermittent progress report.
Since we are talking about the heart listener app which monitors HeartRate devices in the vicinity
we ignore any service that is not of type \l QBluetoothUuid::HeartRate.
\snippet heartlistener/heartrate.cpp Filter HeartRate service 1
Eventually the \l {QLowEnergyController::discoveryFinished()} signal is emitted to indicate
the successful completion of the service discovery. Provided a HeartRate service was found,
a \l QLowEnergyService instance is created to represent the service. The returned service object
provides the required signals for update notifications and the discovery of service details
is triggered using \l QLowEnergyService::discoverDetails():
\snippet heartlistener/heartrate.cpp Filter HeartRate service 2
During the detail search the service's \l {QLowEnergyService::state()}{state()} transitions
from \l {QLowEnergyService::DiscoveryRequired}{DiscoveryRequired} to
\l {QLowEnergyService::DiscoveringServices}{DiscoveringServices} and eventually ends with
\l {QLowEnergyService::ServiceDiscovered}{ServiceDiscovered}:
\snippet heartlistener/heartrate.cpp Find HRM characteristic
\section2 Interaction with the Peripheral Device
In the code example above, the desired characteristic is of type
\l {QBluetoothUuid::HeartRateMeasurement}{HeartRateMeasurement}. Since the application measures
the heart rate changes, it must enable change notifications for the characteristic.
Note that not all characteristics provide change notifications. Since the HeartRate characteristic
has been standardized it is possible to assume that notifications can be received. Ultimately
\l QLowEnergyCharacteristic::properties() must have the \l {QLowEnergyCharacteristic::Notify} flag
set and a descriptor of type \l {QBluetoothUuid::ClientCharacteristicConfiguration} must exist to confirm
the availability of an appropriate notification.
Finally, we process the value of the HeartRate characteristic, as per Bluetooth Low Energy standard:
\snippet heartlistener/heartrate.cpp Reading value 1
\snippet heartlistener/heartrate.cpp Reading value 2
In general a characteristic value is a series of bytes. The precise interpretation of
those bytes depends on the characteristic type and value structure.
A significant number has been standardized by the
\l {https://developer.bluetooth.org/gatt/services/Pages/ServicesHome.aspx}{Bluetooth SIG} whereas others
may follow a custom protocol. The above code snippet demonstrates how to the read the standardized
HeartRate value.
*/
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