A Policy Analytical Approach of Assessing Energy Efficiency Standards and Labeling for Appliances

Zeng, Lei

January 2015

China is the world’s largest producer and consumer of household appliances, lighting and commercial equipment. China first adopted Minimum Energy Performance Standards (MEPS) in 1989. By 2013, China has developed and implemented 52 Energy Efficiency Standards (EES) and 28 mandatory energy labels for a wide range of domestic, commercial, and selected industrial equipment. However, despite of the large number of standards issued, big challenges remain with how to ensure the standards keep up with the dynamic evolvement of technologies and appliance market after they enter effect. The current policy analysis methods adopted by the policy makers primarily focuses on standards making process and very limited attentions were paid on impact assessment and ex-post evaluation of standards and labeling systems, hence the effectiveness of active Energy Efficiency Standards has not been assessed timely and comprehensively. One major barrier of this is the lacking of assessment methods and market data. This thesis intends to tackle the above issues by developing a new policy analysis approach that can be used to assess the impact of energy efficiency standards and labeling with market data. This approach adopts a comprehensive analysis method that comprises three components: (1) Analysis of market data; (2) Quantification of energy savings potential; and (3) Benchmarking China’s EE standards to those of peer economies around the world. This integrated approach leads to three independent but complementary studies that provide evidence-based findings and policy recommendations for the improvement of China’s appliance standards.

Energy Efficiency Standards

Energy Labels

Energy Efficiency Labels

Eco-Labels

Appliance Energy

ENERGY-EFFICIENT SENSING AND COMMUNICATION FOR SECURE INTERNET OF BODIES (IOB)

Baibhab Chatterjee (9524162)

28 July 2022

<p>The last few decades have witnessed unprecedented growth in multiple areas of electronics spanning low-power sensing, intelligent computing and high-speed wireless connectivity. In the foreseeable future, there would be hundreds of billions of computing devices, sensors, things and people, wherein the technology will become intertwined with our lives through continuous interaction and collaboration between humans and machines. Such human-centric ideas give rise to the concept of internet of bodies (IoB), which calls for novel and energy-efficient techniques for sensing, processing and secure communication for resource-constrained IoB nodes.As we have painfully learnt during the pandemic, point-of-care diagnostics along with continuous sensing and long-term connectivity has become one of the major requirements in the healthcare industry, further emphasizing the need for energy-efficiency and security in the resource-constrained devices around us.</p> <p>  </p> <p>  With this vision in mind, I’ll divide this dissertation into the following chapters. The first part (Chapter 2) will cover time-domain sensing techniques which allow inherent energy-resolution scalability, and will show the fundamental limits of achievable resolution. Implementations will include 1) a radiation sensing system for occupational dosimetry in healthcare and mining applications, which can achieve 12-18 bit resolution with 0.01-1 µJ energy dissipation, and 2) an ADC-less neural signal acquisition system with direct Analog to Time Conversion at 13pJ/Sample. The second part (Chapters 3 and 4) of this dissertation will involve the fundamentals of developing secure energy-efficient electro-quasistatic (EQS) communication techniques for IoB wearables as well as implants, and will demonstrate  2 examples: 1) Adiabatic Switching for breaking the αCV^2f limit of power consumption in capacitive voltage mode human-body communication (HBC), and 2) Bi-Phasic Quasistatic Brain Communication (BP-QBC) for fully wireless data transfer from a sub-6mm^3, 2 µW brain implant. A custom modulation scheme, along with adiabatic communication enables wireline-like energy efficiencies (<5pJ/b) in HBC-based wireless systems, while the BP-QBC node, being fully electrical in nature, demonstrates sub-50pJ/b efficiencies by eliminating DC power consumption, and by avoiding the transduction losses observed in competing technologies, involving optical, ultrasound and magneto-electric modalities. Next in Chapter 5, we will show an implementation of a reconfigurable system that would include 1) a human-body communication transceiver and 2) a traditional wireless (MedRadio) transceiver on the same integrated circuit (IC), and would demonstrate methods to switch between the two modes by detecting the placement of the transmitter and receiver devices (on-body/away from the body). Finally, in Chapter 6, we shall show a technique of augmenting security in resource-constrained devices through authentication using the Analog/RF properties of the transmitter, which are usually discarded as non-idealities in a digital transceiver chain. This method does not require any additional hardware in the transmitter, making it an extremely promising technique to augment security in highly resource-constrained scenarios. Such energy-efficient intelligent sensing and secure communication techniques, when combined with intelligent in-sensor-analytics at the resource-constrained nodes, can potentially pave the way for perpetual, and even batteryless systems for next-generation IoT, IoB and healthcare applications.</p>

Data communications

Circuits and systems

Electrical circuits and systems

Analog electronics and interfaces

Digital electronic devices

Electronic sensors

Microelectronics

Radio frequency engineering

Circuits and Systems

energy efficiency standards

Sensing

Time-domain Circuits

Processing

Communication

Human-Body Communication

Wireless

Capacitive

Galvanic

Bi-phasic

MedRadio

RF-PUF

Security