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--- en:iot-reloaded:green_iot_design_tradeoffs [2024/11/28 09:57] – [Green IoT Design Trade-offs] pczekalski
+++ en:iot-reloaded:green_iot_design_tradeoffs [2025/05/13 10:47] (current) – [Green IoT (G-IoT): A Holistic Approach] pczekalski
@@ Line 1: / Line 1: @@
 ====== Green IoT Design Trade-offs ======
-Balancing various design criteria is critical to achieving optimal performance while minimizing environmental impact in designing and implementing IoT devices and infrastructures. The concept of Green IoT (G-IoT) emphasizes designing IoT systems that are energy-efficient, sustainable, and environmentally friendly, addressing the growing concern about the ecological footprint of IoT technologies. However, achieving these goals often involves tradeoffs between competing priorities such as energy consumption, performance, security, cost, and sustainability (figure {{ref>IoTDCES2}}).
+Balancing various design criteria is critical to achieving optimal performance while minimising environmental impact in designing and implementing IoT devices and infrastructures. The concept of Green IoT (G-IoT) emphasises designing IoT systems that are energy-efficient, sustainable, and environmentally friendly, addressing the growing concern about the ecological footprint of IoT technologies. However, achieving these goals often involves trade-offs between competing priorities such as energy consumption, performance, security, cost, and sustainability (figure {{ref>IoTDCES2}}).
 <figure IoTDCES2>
 {{ :en:iot-reloaded:green_iot-page-2.png?600 |Green IoT Design Trade-offs}}
@@ Line 9: / Line 9: @@
 ===== Energy Efficiency =====
-One of the primary design goals in IoT is minimizing energy consumption, as many IoT devices rely on limited-capacity batteries. Energy-efficient hardware components, software optimizations, and low-power communication protocols are widely adopted to prolong device operating lifetimes. For example:
+One of the primary design goals of IoT is minimising energy consumption, as many IoT devices rely on limited-capacity batteries. Energy-efficient hardware components, software optimisations, and low-power communication protocols are widely adopted to prolong device operating lifetimes. For example:
-  * **Energy-Efficient Hardware:** Microcontrollers and sensors optimized for low power draw.
+  * **Energy-Efficient Hardware:** Microcontrollers and sensors optimised for low power draw.
   * **Energy-Efficient Software:** Algorithms designed to reduce computational overhead.
-  * **Low-Power Communication Protocols:** Technologies like Bluetooth Low Energy (BLE) and LoRa minimize power requirements for data transmission.\\
+  * **Low-Power Communication Protocols:** Technologies like Bluetooth Low Energy (BLE) and LoRa minimise power requirements for data transmission.\\
 These measures reduce energy demand and extend battery life. However, the benefit of energy savings often comes at the cost of reduced performance:
   * **Processing Speed:** Energy-efficient hardware may have slower processing capabilities.
   * **Network Bandwidth:** Low-power communication protocols typically support lower data rates, which may not suffice for high-bandwidth applications.
-  * **Packet Loss and Latency:** Optimizations to save power may increase transmission delays or packet loss, affecting Quality of Service (QoS).
+  * **Packet Loss and Latency:** Optimisations to save power may increase transmission delays or packet loss, affecting Quality of Service (QoS).
-===== Security Tradeoffs =====
+===== Security Trade-offs =====
 Security is another critical consideration that often conflicts with energy efficiency in IoT design. Traditional robust security algorithms, such as those used in standard computing systems, are computationally intensive and consume significant energy. Applying such algorithms directly to IoT devices would rapidly deplete their batteries.
@@ Line 26: / Line 26: @@
   * **Energy-Hungry Security Protocols:** Encryption methods like AES-256 or RSA require substantial processing power, which can shorten the device's operational lifetime.
   * **Efforts for Energy-Efficient Security:** Research and development are focused on creating lightweight cryptographic algorithms and authentication mechanisms tailored for resource-constrained IoT devices.\\
-However, prioritizing energy efficiency may compromise the level of security, leaving devices vulnerable to attacks such as data breaches, eavesdropping, or denial of service (DoS).
+However, prioritising energy efficiency may compromise the level of security, leaving devices vulnerable to attacks such as data breaches, eavesdropping, or denial of service (DoS).
 ===== Cost Considerations =====
-Cost is another key factor influencing IoT design. Manufacturers often strive to keep production costs low to ensure the affordability of devices, especially for mass-market applications. This focus on cost reduction may lead to:
+Cost is another key factor influencing IoT design. Manufacturers often strive to keep production costs low to ensure the affordability of devices, especially for mass-market applications. This focus on cost reduction may lead to the following:
   * **Sacrifices in Security:** Inexpensive devices may lack robust security features, increasing the risk of vulnerabilities.
   * **Tradeoffs in Performance and QoS:** Lower-cost components may provide suboptimal computing or communication capabilities.\\
-While minimizing cost is essential for market viability, it can compromise other critical aspects such as reliability, durability, or security, leading to potential issues over the device's lifecycle.
+While minimising cost is essential for market viability, it can compromise other critical aspects, such as reliability, durability, or security, leading to potential issues over the device's lifecycle.
-===== Green IoT (G-IoT): A Holistic Approach =====
+===== Green IoT: A Holistic Approach =====
 Green IoT aims to address the environmental and sustainability challenges associated with IoT systems. It focuses on:
-  * **Minimizing Energy Consumption:** Through energy-efficient designs and renewable energy sources.
+  * **Minimising Energy Consumption:** Through energy-efficient designs and renewable energy sources.
   * **Reducing E-Waste:** Promoting the use of recyclable materials and modular designs to extend device lifecycles.
-  * **Sustainable Applications of IoT:** Leveraging IoT solutions to enhance resource efficiency in industries such as agriculture, transportation, and energy.
+  * **Sustainable Applications of IoT:** Leveraging IoT solutions to enhance resource efficiency in agriculture, transportation, and energy industries.
 Examples include precision farming, smart grids, and waste management systems.
 However, Green IoT design must also balance other key requirements:
-  * **Quality of Service (QoS):** Ensuring that energy and cost optimizations do not compromise performance.
+  * **Quality of Service (QoS):** Ensuring energy and cost optimisations do not compromise performance.
   * **Security:** Developing secure yet lightweight protocols to protect data and device integrity.
   * **Cost-Effectiveness:** Striking a balance between affordability and sustainability without compromising essential functionalities.
-===== Design Challenges and Tradeoff Management =====
+===== Design Challenges and Trade-off Management =====
-Achieving the goals of Green IoT requires careful consideration of tradeoffs:
+Achieving the goals of Green IoT requires careful consideration of trade-offs:
-  * **Energy vs. Performance:** Designers must balance low-power operation with the need for adequate processing and communication capabilities.
+  * **Energy vs. Performance:** Designers must balance low-power operation with adequate processing and communication capabilities.
   * **Security vs. Energy and Cost:** Integrating security features without excessive energy consumption or cost inflation is a significant challenge.
   * **Sustainability vs. Cost:** Sustainable practices, such as using eco-friendly materials or designing for recyclability, may increase initial production costs.\\
-To navigate these tradeoffs, designers can adopt strategies such as:
+To navigate these trade-offs, designers can adopt strategies such as:
   * **Adaptive Systems:** IoT devices that dynamically adjust energy use and processing power based on current requirements.
   * **Edge Computing:** Shifting computational tasks to edge devices to reduce the energy demand on individual IoT nodes.
-  * **Standardization:** Developing universal standards for energy-efficient, secure, and sustainable IoT designs.
+  * **Standardisation:** Developing universal standards for energy-efficient, secure, and sustainable IoT designs.
-Green IoT represents a transformative approach to designing IoT systems that align with environmental and sustainability goals. By addressing energy efficiency, e-waste reduction, and sustainable resource management, Green IoT can contribute to a more sustainable future. However, realizing these benefits requires a balanced approach that considers the tradeoffs between QoS, security, energy efficiency, and cost, ensuring that IoT systems are both functional and eco-friendly.
+Green IoT represents a transformative approach to designing IoT systems that align with environmental and sustainability goals. By addressing energy efficiency, e-waste reduction, and sustainable resource management, Green IoT can contribute to a more sustainable future. However, realising these benefits requires a balanced approach considering the trade-offs between QoS, security, energy efficiency, and cost, ensuring that IoT systems are functional and eco-friendly.

en/iot-reloaded/green_iot_design_tradeoffs.1732787835.txt.gz · Last modified: 2024/11/28 09:57 by pczekalski