Batteryless BLE and Light-based IoT Sensor Nodes for Reliable Environmental Sensing

The sustainable design of Internet of Things (IoT) networks encompasses considerations related to energy efficiency and autonomy as well as considerations related to reliable communications, ensuring no energy is wasted on undelivered data. Under these considerations, this work proposes the design and implementation of energy-efficient Bluetooth Low Energy (BLE) and Light-based IoT (LIoT) batteryless IoT sensor nodes powered by an indoor light Energy Harvesting Unit (EHU). Our design intends to integrate these nodes into a sensing network to improve its reliability by combining both technologies and taking advantage of their features. The nodes incorporate state-of-the-art components, such as low-power sensors and efficient System-on-Chips (SoCs). Moreover, we design a strategy for adaptive switching between active and sleep cycles as a function of the available energy, allowing the IoT nodes to continuously operate without batteries. Our results show that by adapting the duty cycle of the BLE and LIoT nodes depending on the environment's light intensity, we can ensure a continuous and reliable node operation. In particular, measurements show that our proposed BLE and LIoT node designs are able to communicate with an IoT gateway in a bidirectional way, every 19.3 and 624.6 seconds, respectively, in an energy-autonomous and reliable manner.Comment: 6 pages, 9 figures, accepted for publication in the IEEE International Symposium on Personal, Indoor and Mobile Radio Communications (PIMRC 2024), Valencia, Spai

Arduino-Based Lab for Monitoring Biological Processes

This article discusses the design considerations and potential applications of an Arduino-based laboratory for monitoring biological processes. Biological processes such as microbial growth, plant growth, bioreactor operation, and fermentation require the monitoring of environmental factors like temperature, pH, and oxygen levels. The Arduino-based laboratory provides a low-cost, customizable, and user-friendly solution for monitoring these parameters. The article covers the selection of appropriate sensors, calibration methods, power supply considerations, data acquisition and storage techniques, environmental factors, user interface design, and safety measures for the laboratory. The transfer methods and Arduino code for data transfer using Bluetooth and SD card are also provided. The results obtained from monitoring nutrient availability, temperature, pH, and oxygen levels during microorganism propagation are presented, demonstrating the laboratory's accuracy and reliability. The discussion highlights the benefits of using the Arduino-based laboratory, including its low cost, open-source nature, user-friendliness, customization options, real-time monitoring capabilities, and potential for hands-on learning. The conclusion emphasizes the laboratory's accessibility, affordability, and potential to revolutionize the field of biotechnology by promoting collaboration, innovation, and high-quality research. Overall, the Arduino-based laboratory offers a promising solution for monitoring biological processes, providing valuable insights into the behavior of microorganisms and facilitating research and education in various settings

Development of personal area network (PAN) for mobile robot using bluetooth transceiver

The work presents the concept of providing a Personal Area Network (PAN) for microcontroller based mobile robots using Bluetooth transceiver. With the concept of replacing cable, low cost, low power consumption and communication range between 10m to 100m, Bluetooth is suitable for communication between mobile robots since most mobile robots are powered by batteries and have high mobility. The network aimed to support real-time control of up to two mobile robots from a master mobile robot through communication using Bluetooth transceiver. If a fast network radio link is implemented, a whole new world of possibilities is opened in the research of robotics control and Artificial Intelligence (AI) research works, sending real time image and information. Robots could communicate through obstacles or even through walls. Bluetooth Ad Hoc topology provides a simple communication between devices in close by forming PAN. A system contained of both hardware and software is designed to enable the robots to form a PAN and communicating, sharing information. Three microcontroller based mobile robots are built for this research work. Bluetooth Protocol Stack and mobile robot control architecture is implemented on a single microcontroller chip. The PAN enabled a few mobile robots to communicate with each other to complete a given task. The wireless communication between mobile robots is reliable based from the result of experiments carried out. Thus this is a platform for multi mobile robots system and Ad Hoc networking system. Results from experiments show that microcontroller based mobile robots can easily form a Bluetooth PAN and communicate with each other

Design of Low-Power Transmitter and Receiver Front End

This thesis focuses on the design of "RF front-end blocks" for the transmitter and receiver. The blocks include the low noise amplifier (LNA) and mixer downconversion at the receiving side, while the power amplifier includes the pre-driver circuit, and mixer up-conversion at the transmitter side. All of the blocks were designed in a 65nm design kit. The basics of these RF blocks are first described in chapters two to four. After that, the general principle of operations is then described and different topologies are discussed. In chapter 5 the proposed design is discussed. The proposed design is composed of a differential IDCS narrow band LNA, with a passive down-conversion mixer on the receiving side, designed for bluetooth low energy (BLE) applications, that operates at 2.4 GHz with a 1.2 V supply voltage. The overall conversion gain at the receiving side was found to be greater than 13 dB with a double side band noise figure of 8.3 dB having a 1 dB compression point of -11.8 dB, and with IIP3 of -2.06 dBm having a power consumption of 251 μwatts. On the transmission side, a power amplifier with a pre-driver circuit and a passive up-conversion mixer has been designed to operate at a 1.2 V supply at the frequency of operation 2.4 GHz, having overall gain of 24 dB with maximum power added efficiency of 34% when using maximum output power of 11 dBm. The Cadence virtuoso design kit was used for simulation. Additionally, the layout considerations were discussed, followed by presentation of the post-layout results and graphs, and, finally, some conclusions have been drawn

A Reconfigurable Tile-Based Architecture to Compute FFT and FIR Functions in the Context of Software-Defined Radio

Software-defined radio (SDR) is the term used for flexible radio systems that can deal with multiple standards. For an efficient implementation, such systems require appropriate reconfigurable architectures. This paper targets the efficient implementation of the most computationally intensive kernels of two significantly different standards, viz. Bluetooth and HiperLAN/2, on the same reconfigurable hardware. These kernels are FIR filtering and FFT. The designed architecture is based on a two-dimensional arrangement of 17 tiles. Each tile contains a multiplier, an adder, local memory and multiplexers allowing flexible communication with the neighboring tiles. The tile-base data path is complemented with a global controller and various memories. The design has been implemented in SystemC and simulated extensively to prove equivalence with a reference all-software design. It has also been synthesized and turns out to outperform significantly other reconfigurable designs with respect to speed and area

An Analogue Front-End Test-Bed for Software Defined Radio

A Software Defined Radio (SDR) is a radio receiver and/or transmitter, whose characteristics can to a large extent be defined by software. Thus, an SDR can receive and/or transmit a wide variety of signals, supporting many different standards. In our research, we currently focus on a demonstrator that is able to receive both Bluetooth and HiperLAN/2. This helps us to identify problems associated with SDR, and will provide a test-bed for possible solutions to these problems. The two standards differ significantly in characteristics like frequency band, signal bandwidth and modulation type. Combining two different standards in one receiver appears to pose new design challenges. For example, in the wide frequency range that we want to receive, many strong signals\ud may exist. This leads to severe linearity requirements for wideband receivers. This paper describes some receiver architectures. One\ud design has been selected. This receiver has been built, and some measurement results are included

Power-Constrained Fuzzy Logic Control of Video Streaming over a Wireless Interconnect

Wireless communication of video, with Bluetooth as an example, represents a compromise between channel conditions, display and decode deadlines, and energy constraints. This paper proposes fuzzy logic control (FLC) of automatic repeat request (ARQ) as a way of reconciling these factors, with a 40% saving in power in the worst channel conditions from economizing on transmissions when channel errors occur. Whatever the channel conditions are, FLC is shown to outperform the default Bluetooth scheme and an alternative Bluetooth-adaptive ARQ scheme in terms of reduced packet loss and delay, as well as improved video quality

Wearable Communications in 5G: Challenges and Enabling Technologies

As wearable devices become more ingrained in our daily lives, traditional communication networks primarily designed for human being-oriented applications are facing tremendous challenges. The upcoming 5G wireless system aims to support unprecedented high capacity, low latency, and massive connectivity. In this article, we evaluate key challenges in wearable communications. A cloud/edge communication architecture that integrates the cloud radio access network, software defined network, device to device communications, and cloud/edge technologies is presented. Computation offloading enabled by this multi-layer communications architecture can offload computation-excessive and latency-stringent applications to nearby devices through device to device communications or to nearby edge nodes through cellular or other wireless technologies. Critical issues faced by wearable communications such as short battery life, limited computing capability, and stringent latency can be greatly alleviated by this cloud/edge architecture. Together with the presented architecture, current transmission and networking technologies, including non-orthogonal multiple access, mobile edge computing, and energy harvesting, can greatly enhance the performance of wearable communication in terms of spectral efficiency, energy efficiency, latency, and connectivity.Comment: This work has been accepted by IEEE Vehicular Technology Magazin