Blue Star

Blue Star

MATLAB EXPO China

星期日, 05 06月 2022
June 21 - 24, 2022 | Online
Discover the latest MATLAB and Simulink capabilities at MATLAB EXPO 2022.

Featured Presentations (Additional Proceedings)

See additional dates and locations.
Functions of PHY Modeling,Coexistence Modeling,Localization,Test and Measurement,End-to-End Simulation,Multinode Communication,Mesh Networking,Piconet,Bluetooth LE Node,Waveform Generation and Reception,PDU Generation,PDU Decoding,Bluetooth LE Node,PDU Configuration,PCAP and PCAPNG File Writing,Bluetooth Audio
The Bluetooth low energy (LE) network simulation captures these statistics as a structure. This structure is returned as an output by the statistics object function of the bluetoothLENode object. The fields of this structure depend on the value of the Role property of the bluetoothLENode object.
Bluetooth® [1] wireless technology is the air interface intended to replace the cables connecting portable and fixed electronic equipment. Bluetooth device manufacturers have the flexibility to include optional core specification features to optimize and differentiate product offers.
The Bluetooth® Special Interest Group (SIG) [1] and [2] defines the protocol stack for Bluetooth low energy (LE) and Bluetooth basic rate/enhanced data rate (BR/EDR) technology. The fundamental objectives of these specifications is to develop interactive services and applications over interoperable radio components and data communication protocols.

MathWorks Bluetooth® Toolbox provides standard-based tools to design, simulate, and verify Bluetooth communications systems. It supports test waveform generation, golden reference verification, and Bluetooth network modeling.

With the toolbox, you can configure, simulate, and analyze end-to-end Bluetooth communication links. You can create and reuse test benches to verify that your designs, prototypes, and implementations comply with the Bluetooth standard, including Bluetooth basic rate/enhanced data rate (BR/EDR) and low energy (LE). You can also assess coexistence, interference, localization, and LE Audio scenarios by modeling multiple layers of the Bluetooth protocol stack.

CAN-BUS sniffing for Volkswagen Golf MK7 (and most likely other MQB platform cars). Currently this is more a work log for future reference.

This example shows you how to track the 2-D or 3-D position of a Bluetooth® low energy (LE) node by using Bluetooth® Toolbox.

Using this example, you can:

  • Simulate direction-finding packet exchange in the presence of radio frequency (RF) front end impairments, path loss, and additive white Gaussian noise (AWGN).

  • Track the node position by using Bluetooth direction-finding features and position estimation techniques.

  • Improve the location accuracy by using a Kalman filter from Sensor Fusion and Tracking Toolbox™.

The Bluetooth® Special Interest Group (SIG) [1] and [2] defines the protocol stack for Bluetooth low energy (LE) and Bluetooth basic rate/enhanced data rate (BR/EDR) technology. The fundamental objectives of these specifications is to develop interactive services and applications over interoperable radio components and data communication protocols.
Bluetooth Low Energy (formerly known as Bluetooth Smart) is a wireless communication protocol that uses Bluetooth with low-power peripheral devices. These peripheral devices include fitness trackers, health monitors, and personal electronics such as smartwatches or wireless headphones.