bluetoothLENode
Download Required: To use bluetoothLENode
,
first download the Communications Toolbox Wireless Network Simulation Library add-on. For more
information, see Get and Manage Add-Ons.
Description
Use the bluetoothLENode
object to create and configure a
Bluetooth® low energy (LE) node.
Creation
Syntax
Description
creates a default
Bluetooth LE node object with a LENode
= bluetoothLENode"peripheral"
role.
creates a Bluetooth LE node object with the Role
property set to LENode
= bluetoothLENode(role
)role
.
sets the properties of
the Bluetooth LE node object with a LENode
= bluetoothLENode(Name=Value
)"peripheral"
role by using one or
more optional name-value arguments. For example, TransmitterPower=0
sets the transmitter power of the Peripheral node to 0 dBm.
You can use this syntax to generate an array of Bluetooth LE node objects by
specifying the value of the Position
property.
creates a Bluetooth LE node object with the Role
property set to LENode
= bluetoothLENode(role
,Name=Value
)role
and the other properties
specified by using one or more optional name-value arguments. For example,
"central",TransmitterPower=0
sets the transmitter power of the
Central node to 0 dBm.
Properties
Role
— Role of the Bluetooth LE Node
"peripheral"
(default) | "central"
| "broadcaster"
| "observer"
| "isochronous-broadcaster"
| "synchronized-receiver"
| "broadcaster-observer"
This property is read-only.
Role of the Bluetooth LE node, specified as one of these values.
Role Value | Description |
---|---|
"central" | Simulate Bluetooth LE node scenario |
"peripheral" | Simulate Bluetooth LE node scenario |
"broadcaster" | Simulate Bluetooth LE node scenario with periodic or legacy advertisements |
"observer" | Simulate Bluetooth LE node scenario with periodic advertisements |
"isochronous-broadcaster" | Simulate Bluetooth LE broadcast audio network |
"synchronized-receiver" | Simulate Bluetooth LE broadcast audio network |
"broadcaster-observer" | Simulate Bluetooth LE mesh network |
The role
argument sets the value of this property.
Data Types: char
| string
Position
— Node position in 3-D Cartesian coordinates
[0 0 0]
(default) | numeric N-by-3 matrix
Node Position in 3-D Cartesian coordinates, specified as a numeric
N-by-3 matrix. N specifies the number of
Bluetooth LE nodes. This value specifies the position of the node in Cartesian x-, y-,
and z-coordinates. When you specify this value as a matrix with N >
1, you create a 1-by-N array of the bluetoothLENode
object. Units are in meters. Note that if the Role
value is "broadcaster-observer"
and you specify the MeshConfig property to create mesh nodes, you can only create one node at
a time, and N must be 1.
Data Types: double
Name
— Node name
"NodeN"
(default) | character vector | string scalar | string array | cell array of character vectors
Node name, specified as a character vector, string scalar, string array, or cell
array of character vectors. The default format of this value is
"NodeN"
, where N is the
node identifier specified by the ID
property. When you specify the Position
property to create an array of the bluetoothNode
objects, you can
simultaneously name each node in the array by providing this value as a string array or
a cell array of character vectors. If you specify this value as an array that exceeds
the number of nodes, the object does not use the surplus names. Conversely, if you
specify this value as an array that is smaller than the number of nodes, the object
assigns default names to the additional nodes.
Data Types: char
| string
TransmitterPower
— Signal transmission power
20
(default) | scalar in the range [-20, 20]
Signal transmission power, specified as a scalar in the range [-20, 20]. Specify this value in dBm. This value specifies the average power that the transmitter applies to the Bluetooth LE signal before sending it to the antenna.
Data Types: double
TransmitterGain
— Transmitter antenna gain
0
(default) | finite numeric scalar
Transmitter antenna gain, specified as a finite numeric scalar. Specify this value in dB.
Data Types: double
ReceiverRange
— Packet reception range of node
100
(default) | finite positive scalar
Packet reception range of node, specified as a finite positive scalar. Specify this value in meters. If a receiving node receives a signal from a sending node located beyond this value, the receiving node drops the received signal. To reduce the processing complexity of the simulation, set this property to a smaller value.
Data Types: double
ReceiverGain
— Receiver antenna gain
0
(default) | finite numeric scalar
Receiver antenna gain, specified as a finite numeric scalar. Specify this value in dB.
Data Types: double
ReceiverSensitivity
— Receiver sensitivity
-100
(default) | finite numeric scalar
Receiver sensitivity, specified as a finite numeric scalar. Specify this value in dBm. This property sets the minimum received power to detect the incoming signal. If the received power of an incoming signal is below this value, the node considers the signal invalid.
Data Types: double
NoiseFigure
— Noise figure
0
(default) | finite nonnegative numeric scalar
Noise figure, specified as a finite nonnegative numeric scalar. Specify this value in dB. Use this value to add thermal noise to the received signal.
Data Types: double
AdvertisingInterval
— Advertising interval
0.02
(default) | scalar in the range [0.02, 10485.759375]
Advertising interval, specified as a scalar in the range [0.02, 10485.759375]. Specify this value in seconds. You must set this value as an integer multiple of 0.625 milliseconds. This value specifies the interval of an advertising event during which the transmission of advertising packets occurs.
Data Types: double
RandomAdvertising
— Random advertising channel selection
0
or false
(default) | 1
or true
Random advertising channel selection, specified as 0
(false
) or 1
(true
). To model
the random selection of advertising channels, set this value to
true
.
Data Types: logical
ScanInterval
— Scan interval
0.005
(default) | scalar in the range [0.0025, 40.960]
Scan interval, specified as a scalar in the range [0.0025, 40.960]. Specify this value in seconds. You must set this value as an integer multiple of 0.625 milliseconds. This value specifies the interval in which the node listens for the advertising packets.
Data Types: double
MeshConfig
— Bluetooth mesh profile configuration parameters
bluetoothMeshProfileConfig
object
Bluetooth mesh profile configuration parameters, specified as a bluetoothMeshProfileConfig
object.
Dependencies
To enable this property, set the Role
property to "broadcaster-observer"
.
InterferenceModeling
— Type of interference modeling
"overlapping-adjacent-channel"
(default) | "non-overlapping-adjacent-channel"
Type of interference modeling, specified as
"overlapping-adjacent-channel"
or
"non-overlapping-adjacent-channel"
.
"overlapping-adjacent-channel"
— The object considers signals overlapping in time and frequency to be interference."non-overlapping-adjacent-channel"
— In addition to signals that satisfy the conditions described under"overlapping-adjacent-channel"
, the object considers signals that overlap with the SOI in time and with the interval [f1 – fd, f2 + fd] in frequency to be interference. f1 and f2 are the starting and ending frequencies of the SOI, respectively. fd is the value of the MaxInterferenceOffset property.
Data Types: char
| string
MaxInterferenceOffset
— Maximum frequency offset for determining signal interference
100e6
(default) | nonnegative scalar
Maximum frequency offset for determining signal interference, specified as a
nonnegative scalar. Units are in Hz. This property specifies the offset between the edge
of the SOI frequency and the edge of the interfering signal. If you specify this
property as Inf
, the object considers all the signals that overlap in
time, regardless of their frequency, to be interference. If you specify this property as
a finite nonnegative scalar, the object considers all the signals overlapping in time
and with frequency in the range [(f1 –
),
(f2 +
MaxInterferenceOffset
)], to be
interference.MaxInterferenceOffset
Dependencies
To enable this property, set the InterferenceModeling property to
"non-overlapping-adjacent-channel"
.
Data Types: double
ID
— Node identifier
scalar integer
This property is read-only.
Node identifier, returned as an integer. This value specifies a unique identifier for the node in the simulation.
Note
If you create and store the Bluetooth LE nodes in an uninitialized matrix, the IDs that this property allocates to the nodes can be nonsequential because of the memory allocation to the object in the matrix. For more information about MATLAB memory allocation, see How MATLAB Allocates Memory.
Data Types: double
ConnectionConfig
— Bluetooth LE link layer (LL) connection configuration parameters
bluetoothLEConnectionConfig
object
This property is read-only.
Bluetooth LE LL connection configuration parameters, returned as a bluetoothLEConnectionConfig
object.
Dependencies
To enable this property, set the Role
property to "central"
or "peripheral"
.
CISConfig
— CIS connection configuration object
bluetoothLECISConfig
object | array of objects of type bluetoothLECISConfig
This property is read-only.
Connected isochronous stream (CIS) connection configuration object, specified as a
bluetoothLECISConfig
object or an array of objects of type
bluetoothLECISConfig
. To configure multiple CIS connections, set this
property as an array of objects of type bluetoothLECISConfig
. Note that
you can configure a maximum of 31 CIS connections.
Dependencies
To enable this property, set the Role
property to "central"
or "peripheral"
.
PeriodicAdvConfig
— Periodic advertising configuration object
object or an array of objects of type
bluetoothLEPeriodicAdvConfig
This property is read-only.
Periodic advertising configuration object, returned as an object or an array of
objects of the type bluetoothLEPeriodicAdvConfig
. This property specifies the synchronization
information shared between the Broadcaster and Observer as part of the periodic
advertisements establishment process.
Dependencies
To enable this property, set the Role
property to "broadcaster"
or "observer"
.
PeripheralCount
— Number of Peripheral nodes associated with Central node
0
(default) | integer
This property is read-only.
Number of Peripheral nodes associated with Central node, returned as an integer.
Dependencies
To enable this property, set the Role
property to "central"
.
Data Types: double
BIGConfig
— Bluetooth LE broadcast isochronous group (BIG) configuration parameters
bluetoothLEBIGConfig
object
This property is read-only.
Bluetooth LE BIG configuration parameters, returned as a bluetoothLEBIGConfig
object.
Dependencies
To enable this property, set the Role
property to "isochronous-broadcaster"
or
"synchronized-receiver"
.
FriendshipConfig
— Bluetooth mesh friendship configuration object for Friend and low power node (LPN)
bluetoothMeshFriendshipConfig
object
This property is read-only.
Friendship configuration object for Friend and LPN, returned as a bluetoothMeshFriendshipConfig
object.
Dependencies
To enable this property, set the Role
property to "broadcaster-observer"
.
Object Functions
Specific to This Object
addMobility | Add random waypoint mobility model to Bluetooth LE node |
addTrafficSource | Add data traffic source to Bluetooth LE node |
updateChannelList | Provide updated channel list to Bluetooth LE node |
kpi | Returns key performance indicators (KPIs) for Bluetooth LE nodes |
statistics | Get statistics of Bluetooth LE node |
Examples
Create, Configure, and Simulate Bluetooth LE Network With Custom Channel
This example shows you how to simulate a Bluetooth® low energy (LE) network with a custom channel by using Bluetooth® Toolbox and Communications Toolbox™ Wireless Network Simulation Library.
Using this example, you can:
Create and configure a Bluetooth LE piconet with Central and Peripheral nodes.
Create and configure a link layer (LL) connection between Central and Peripheral nodes.
Add application traffic from the Central to Peripheral nodes.
Create a custom channel, and plug it into the wireless network simulator.
Simulate Bluetooth LE network and retrieve the statistics of the Central and Peripheral nodes.
Check if the Communications Toolbox Wireless Network Simulation Library support package is installed. If the support package is not installed, MATLAB® returns an error with a link to download and install the support package.
wirelessnetworkSupportPackageCheck
Create a wireless network simulator.
networkSimulator = wirelessNetworkSimulator.init;
Create a Bluetooth LE node, specifying the role as "central"
. Specify the name and position of the node.
centralNode = bluetoothLENode("central"); centralNode.Name = "CentralNode"; centralNode.Position = [0 0 0]; % In x-, y-, and z-coordinates in meters
Create a Bluetooth LE node, specifying the role as "peripheral"
. Specify the name and position of the node.
peripheralNode = bluetoothLENode("peripheral"); peripheralNode.Name = "PeripheralNode"; peripheralNode.Position = [10 0 0] % In x-, y-, and z-coordinates in meters
peripheralNode = bluetoothLENode with properties: TransmitterPower: 20 TransmitterGain: 0 ReceiverRange: 100 ReceiverGain: 0 ReceiverSensitivity: -100 NoiseFigure: 0 InterferenceModeling: "overlapping-adjacent-channel" InterferenceFidelity: 0 Name: "PeripheralNode" Position: [10 0 0] Read-only properties: Role: "peripheral" ConnectionConfig: [1x1 bluetoothLEConnectionConfig] CISConfig: [1x1 bluetoothLECISConfig] TransmitBuffer: [1x1 struct] ID: 2
Add a random waypoint mobility model to the Bluetooth peripheral node. Set the shape of the node's mobility area to "circle"
.
addMobility(peripheralNode,BoundaryShape="circle");
Create a default Bluetooth LE configuration object to share the LL connection between the Central and Peripheral nodes.
cfgConnection = bluetoothLEConnectionConfig;
Specify the connection interval and connection offset. Throughout the simulation, the object establishes LL connection events for the duration of each connection interval. The connection offset is from the beginning of the connection interval.
cfgConnection.ConnectionInterval = 0.01; % In seconds cfgConnection.ConnectionOffset = 0; % In seconds
Specify the active communication period after the connection event is established between the Central and Peripheral nodes.
cfgConnection.ActivePeriod = 0.01 % In seconds
cfgConnection = bluetoothLEConnectionConfig with properties: ConnectionInterval: 0.0100 AccessAddress: "5DA44270" UsedChannels: [0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36] Algorithm: 1 HopIncrement: 5 CRCInitialization: "012345" SupervisionTimeout: 1 PHYMode: "LE1M" InstantOffset: 6 ConnectionOffset: 0 ActivePeriod: 0.0100
Configure the connection between Central and Peripheral nodes by using the configureConnection
object function of the bluetoothLEConnectionConfig
object.
configureConnection(cfgConnection,centralNode,peripheralNode);
Create a networkTrafficOnOff
object to generate an On-Off application traffic pattern. Specify the data rate in kb/s and the packet size in bytes. Enable packet generation to generate an application packet with a payload.
traffic = networkTrafficOnOff(DataRate=100, ... PacketSize=10, ... GeneratePacket=true);
Add application traffic from the Central to the Peripheral node by using the addTrafficSource
object function.
addTrafficSource(centralNode,traffic,"DestinationNode",peripheralNode.Name);
Create a Bluetooth LE network consisting of a Central and a Peripheral node.
nodes = {centralNode peripheralNode};
Add the Central and Peripheral nodes to the wireless network simulator.
addNodes(networkSimulator,nodes)
Add the custom channel to the wireless network simulator.
addChannelModel(networkSimulator,@addImpairment);
Set the simulation time in seconds and run the simulation.
simulationTime = 0.5; run(networkSimulator,simulationTime)
Retrieve application, link layer (LL), and physical layer (PHY) statistics corresponding to the Central and Peripheral nodes. For more information about the statistics, see Bluetooth LE Node Statistics.
centralStats = statistics(centralNode)
centralStats = struct with fields:
Name: "CentralNode"
ID: 1
App: [1x1 struct]
LL: [1x1 struct]
PHY: [1x1 struct]
peripheralStats = statistics(peripheralNode)
peripheralStats = struct with fields:
Name: "PeripheralNode"
ID: 2
App: [1x1 struct]
LL: [1x1 struct]
PHY: [1x1 struct]
Follow these steps to create a custom channel that models Bluetooth path loss for an industrial scenario.
Create a custom function with this syntax:
rxData = customFcnName(rxInfo,txData)
. TherxInfo
input specifies the receiver node information as a structure, and thetxData
input specifies the transmitted packets as a structure. The simulator automatically passes information about the receiver node and the packets transmitted by a transmitter node as inputs to the custom function. For more information about creating custom channel, see theaddChannelModel
object function.Use the
bluetoothPathLossConfig
object to set path loss configuration parameters for an industrial scenario.Calculate path loss between the Central and Peripheral nodes using the
bluetoothPathLoss
function. Specify the transmitter and receiver positions.Apply path loss to the transmitted packets.
function rxData = addImpairment(rxInfo,txData) pathlossCfg = bluetoothPathLossConfig(Environment="Industrial"); % Apply path loss and update output signal rxData = txData; % Calculate the distance between transmitter and receiver in meters distance = norm(rxData.TransmitterPosition - rxInfo.Position); pathloss = bluetoothPathLoss(distance,pathlossCfg); rxData.Power = rxData.Power-pathloss; % In dBm scale = 10.^(-pathloss/20); [numSamples,~] = size(rxData.Data); rxData.Data(1:numSamples,:) = rxData.Data(1:numSamples,:)*scale; end
More About
Events
Events are occurrences that the object triggers in response to an action such as a change in a property value or a user interaction with the application program. Listeners execute functions when notified that the event of interest occurs. Listeners respond by executing a callback function that has at least two input arguments defined, the event source object handle and the event data. For more information about events and listeners, see Overview Events and Listeners and Event and Listener Concepts.
The bluetoothLENode
object defines these events.
PacketTransmissionStarted
When a node starts transmitting a packet, the object triggers the
PacketTransmissionStarted
event. This event passes an event notification
and this structure as event data to the registered callback.
Field | Value | Description |
---|---|---|
NodeName | character vector | Node name, specifying the Name property of the Bluetooth LE node that starts the packet
transmission |
NodeID | scalar positive integer | Unique node identifier, specifying the ID property of the Bluetooth LE node that starts the packet transmission |
CurrentTime | scalar positive integer | Current time of the simulation in seconds |
PDU | binary column vector | Protocol data unit (PDU) bits to be transmitted |
AccessAddress | character vector representing a 4-octet hexadecimal number | Access address of the Bluetooth LE packet |
ChannelIndex | integer in the range [0, 39] | Channel index for transmission |
PHYMode |
| Physical layer (PHY) transmission mode |
TransmittedPower | scalar | Transmit power in dBm |
PacketDuration | scalar positive integer | Packet duration in seconds. |
PacketReceptionEnded
When the reception of a packet ends, the object triggers the
PacketReceptionEnded
event. This event passes an event notification and
this structure as event data to the registered callback.
Field | Value | Description |
---|---|---|
NodeName | character vector | Node name, specifying the Name property of the Bluetooth LE node that receives the
packet |
NodeID | scalar positive integer | Unique node identifier, specifying the ID property of the Bluetooth LE node that receives the packet |
CurrentTime | scalar positive integer | Current time of the simulation in seconds |
SourceNode | character vector | Name of the source node, specifying the Name property of the Bluetooth LE node that starts the packet
transmission |
SourceID | scalar positive integer | Unique node identifier, specifying the ID property of the Bluetooth LE node that starts the packet transmission |
SuccessStatus | logical scalar | Flag indicating the success status of the packet |
PDU | binary column vector | PDU bits received |
AccessAddress | character vector representing a 4-octet hexadecimal number | Access address of the packet |
ChannelIndex | integer in the range [0, 39] | Channel index for reception |
PHYMode |
| PHY reception mode |
PacketDuration | positive scalar or | Duration of the received packet in seconds |
ReceivedPower | scalar | Received power in dBm |
SINR | scalar | Signal-to-interference plus noise ratio in dB |
ChannelMapUpdated
When the node starts using the updated channel map of the link, the object triggers
the ChannelMapUpdated
event. This event passes an event notification and
this structure as event data to the registered callback.
Field | Value | Description |
---|---|---|
NodeName | character vector | Node name, specifying the Name property of the Bluetooth LE node at which the channel map is
updated |
NodeID | scalar positive integer | Unique node identifier, specifying the ID property of the Bluetooth LE node at which the channel map is updated |
CurrentTime | scalar positive integer | Current time of the simulation in seconds |
PeerNode | character vector | Name of the peer node, specifying the Name property of the Bluetooth LE at which the channel map is
updated |
PeerID | scalar positive integer | Unique node identifier of the peer node, specifying the ID property of the Bluetooth LE node at which the channel map is updated |
UpdatedChannelList | vector of integers in the range [0, 36] | List of good channels |
AppDataReceived
When there is data for the application from the node, the object triggers the
AppDataReceived
event. This event passes an event notification and this
structure as event data to the registered callback.
Field | Value | Description |
---|---|---|
NodeName | character vector | Node name, specifying the Name property of the Bluetooth LE node at which the application
data is destined |
NodeID | scalar positive integer | Unique node identifier, specifying the ID property of the Bluetooth LE node at which the application data is destined |
CurrentTime | scalar positive integer | Current time of the simulation in seconds |
SourceNode | character vector | Name of the source node, specifying the Name property of the Bluetooth LE node whose application data is
received. |
ReceivedData | vector of integers in the range [0, 255] | Received application data in decimal bytes |
MeshAppDataReceived
When application data is received for a mesh node, the object triggers the
MeshAppDataReceived
event. This event passes an event notification and
this structure as event data to the registered callback.
Field | Value | Description |
---|---|---|
NodeName | character vector | Node name, specifying the Name property of the Bluetooth LE node at which the application
data is destined |
NodeID | scalar positive integer | Unique node identifier, specifying the ID property of the Bluetooth LE node at which the application data is destined |
CurrentTime | scalar positive integer | Current time of the simulation in seconds |
Message | vector of integers in the range [0, 255] | Received access message |
SourceAddress | character vector representing a 2-octet hexadecimal number | Source address of the message, specifying the Name property of the Bluetooth LE node that is the destination for
the application data |
DestinationAddress | character vector representing a 2-octet hexadecimal number | Destination address of the message, specifying the Name property of the Bluetooth LE node at which the application
data is destined |
ConnectionEventEnded
When the connection event ends, the object triggers the
ConnectionEventEnded
event. This event passes an event notification and
this structure as event data to the registered callback.
Field | Value | Description |
---|---|---|
NodeName | character vector | Node name, specifying the Name property of the Bluetooth LE node at which the connection
event ends |
NodeID | scalar positive integer | Unique node identifier, specifying the ID property of the Bluetooth LE node at which the connection event ends |
CurrentTime | scalar positive integer | Current time of the simulation in seconds |
Counter | scalar positive integer in the range [0, 65535] | Current connection event counter |
TransmittedPackets | scalar nonnegative integer | Number of transmitted packets in the connection event |
ReceivedPackets | scalar nonnegative integer | Number of received packets in the connection event |
CRCFailedPackets | scalar nonnegative integer | Number of received packets with cyclic redundancy check (CRC) failure |
References
[1] Bluetooth Technology Website. “Bluetooth Technology Website | The Official Website of Bluetooth Technology.” Accessed April 22, 2024. https://www.bluetooth.com/.
[2] Bluetooth Core Specifications Working Group. "Bluetooth Core Specification" v5.3. https://www.bluetooth.com/.
Version History
Introduced in R2022aR2024b: InterferenceFidelity
property will be removed
The
property issues a
warning that it will be removed in a future release. Use the new InterferenceFidelity
InterferenceModeling
property
instead. For code that uses the default interference modeling, you do not need to make any
changes as the object manages the transition internally. However, if you have explicitly set
the InterferenceFidelity
property, you must change the property name
from InterferenceFidelity
to InterferenceModeling
,
and modify the value from 0
or 1
to
"overlapping-adjacent-channel"
or
"non-overlapping-adjacent-channel"
, respectively. This table shows the
change in syntax after this update.
Syntax Before This Update | Syntax After This Update |
---|---|
bluetoothLENode(“central”,InterferenceFidelity=0) |
bluetoothLENode(“central”,InterferenceModeling=”overlapping-adjacent-channel”) |
bluetoothLENode(“peripheral”,InterferenceFidelity=1) |
bluetoothLENode(“peripheral”,InterferenceModeling=”non-overlapping-adjacent-channel”) |
R2024a: Model interference at Bluetooth LE node
These two new properties of the bluetoothLENode
object enable you to
model interference by considering signals overlapping in the time and frequency domains.
InterferenceModeling
— Use this property to set the type of interference modeling.
— Use this property to specify the offset between the edge of the SOI frequency and the edge of the interfering signal.MaxInterferenceOffset
R2024a: InterferenceFidelity
property will be removed
The
property will be
removed in a future release. Use the new InterferenceFidelity
InterferenceModeling
property
instead. For code that uses the default interference modeling, you do not need to make any
changes as the object manages the transition internally. However, if you have explicitly set
the InterferenceFidelity
property, you must change the property name
from InterferenceFidelity
to InterferenceModeling
,
and modify the value from 0
or 1
to
"overlapping-adjacent-channel"
or
"non-overlapping-adjacent-channel"
, respectively. This table shows the
change in syntax after this update.
Syntax Before This Update | Syntax After This Update |
---|---|
bluetoothLENode(“central”,InterferenceFidelity=0) |
bluetoothLENode(“central”,InterferenceModeling=”overlapping-adjacent-channel”) |
bluetoothLENode(“peripheral”,InterferenceFidelity=1) |
bluetoothLENode(“peripheral”,InterferenceModeling=”non-overlapping-adjacent-channel”) |
R2023a: Includes support for adding random waypoint mobility model to Bluetooth LE node
The bluetoothLENode
object now supports adding a random waypoint
mobility model to Bluetooth LE nodes through the addMobility
object function.
See Also
Objects
wirelessNetworkSimulator
|bluetoothNode
|bluetoothLEConnectionConfig
|bluetoothLEBIGConfig
|bluetoothMeshProfileConfig
|bluetoothMeshFriendshipConfig
|bluetoothLECISConfig
|bluetoothLEPeriodicAdvConfig
Topics
- Create, Configure, and Simulate Bluetooth LE Network With Custom Channel
- Create, Configure, and Simulate Bluetooth LE Broadcast Audio Network
- Create, Configure and Simulate Bluetooth Mesh Network
- Estimate Packet Delivery Ratio of LE Broadcast Audio in Residential Scenario
- Establish Friendship Between Friend Node and LPN in Bluetooth Mesh Network
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