Any problem becomes tractable with enough power. Since the inception of wireless sensornetworks, researchers have searched for ways to do more with less. Integrated circuits and
sensors have continued to shrink in size, cost, and active and quiescent power. This has
resulted in sensors with increasing computational power and longer lifetimes. By comparison,
however, the options for and quantity of power available for a wireless sensor has stagnated.
The energy density of non-rechargeable batteries as well as photovoltaic efficiency have
approached a plateau. As a result, wireless sensors are constrained in either lifetime or power.
Technology improvements like integrated circuits that perform efficient maximum powertracking and voltage boosting, near-threshold computing, the advent of non-volatile memory
technologies, and the rapid improvement of supercapacitor technology has enabled the
development of sensors that can operate entirely on harvested power without batteries,
and without a finite lifetime. But the lack of a reliable power source necessarily results in
a system that is fundamentally unreliable. Despite this significant flaw, researchers have
pursued this design archetype tirelessly, producing an impressive corpus of methods, systems,
and solutions that attempt to improve batteryless design. Proponents of batteryless systems
are convinced that batteries are a threat to the future of wireless sensing, and that batteryless
sensing is the only way forward. Despite this, batteryless sensing has not seen widespread
adoption by industry. There is a rift of design understanding between those who value
reliability, and those who do not.
The core argument of this dissertation is that there is not a single design dogma, be itbatteryless or battery-powered, that can provide a solution for all applications. Instead,
the correct design process must involve a balancing act of the inclusion and sizing of energy
harvesting, rechargeable, and non-rechargeable energy storage to meet the goals of the
application. This design space is large and difficult to navigate, resulting in many system
designers defaulting to following a predetermined design template archetype instead of fully
reasoning about their application and its requirements. In this dissertation, we develop a
design framework for energy harvesting systems that provides reasoned guidance for the
inclusion and sizing of various power supply elements. In particular, we develop analytical
and simulation tools to size rechargeable energy capacity in a more reasoned way than current
heuristics and arbitrary methods.
To develop this design framework, this dissertation explores previous wireless sensor applications, identifying the appropriateness of different approaches qualitatively and quantitatively.We explore the system-level effects of harvester size and rechargeable and non-rechargeable
energy capacity on wireless sensor application performance. To determine rechargeable energy
capacity selection and sizing, we develop a novel heuristic for determining the minimum
sufficient capacity for a sensor workload and expected energy income. We verify this heuristic through the use of a custom wireless sensor energy state simulator to estimate energy
utilization and system performance. To identify technology options for energy capacity, we
quantitatively compare energy buffer types and reevaluate the many qualitative claims made
against rechargeable batteries by batteryless proponents, concluding that many of them are
without merit. Finally, we utilize the design framework developed within this dissertation,
including the heuristics and simulation tool, to design and implement wireless sensor systems to address two real indoor sensing applications that achieve long-lived operation with
consistent and reliable sensing
