Dual-Source Energy-Harvesting Interface With Cycle-by-Cycle Source Tracking and Adaptive Peak-Inductor-Current Control

“…This work is compared with the state-of-the-art multiple source energy harvesting architectures, as tabulated in Table 2. Two of the MidB architectures [20,21] have distinct advantages over the PostB architecture [15] in terms of number of inductors and complexity, but they require external supports to start up. Other works [16,22] utilize batteries to operate.…”

“…In order to lower the number of components (e.g., inductors) and reduce the effects of redundancy and leakage losses, multiinput energy harvesters have been designed with a single inductor boost converter [16,17,[19][20][21][22]. Figure 1a shows a block diagram of a multiinput single inductor (MISI) energy harvesting architecture.…”

“…one energy source is exploited over one switching cycle [16,17,19,21,22], or simultaneously, i.e. two energy sources can be utilized over one switching cycle [20] via switches. However, these switches require a supply power to turn on/off to create a bridge between the energy transducers and the converter to power the load.…”

“…Due to the relatively low voltages generated at energy transducers' outputs [1,5,15,21,30], the output of these energy transducers is insufficient to turn switches M1-Mn on/off, as the threshold voltage of the standard CMOS technology is typically higher than the energy transducer output voltage. Therefore, in order to provide initial operation for a short time, M1-Mn switches in MISI architectures are powered by a battery [16,17,20,21].…”

“…Thus, driving a WSN application through a power converter via a single energy source (e.g., PV) might not be an effective solution to best exploit the energy harvesting. For this reason, efforts to combine and utilize multiple energy sources are gaining popularity among energy harvesting researchers [12][13][14][15][16][17][18][19][20][21][22][23]. By combining multiple energy sources of the same or different types for flexibility, redundancy, or capacity [24], it is possible to improve system reliability [12, 16-19, 21, 23], achieve robustness against power failures [14,15], and increase the overall output power [12][13][14][15][16][17][18][19][20][21][22][23][24].…”

A fully batteryless multiinput single inductor single output energy harvesting architecture

“…This work is compared with the state-of-the-art multiple source energy harvesting architectures, as tabulated in Table 2. Two of the MidB architectures [20,21] have distinct advantages over the PostB architecture [15] in terms of number of inductors and complexity, but they require external supports to start up. Other works [16,22] utilize batteries to operate.…”

“…In order to lower the number of components (e.g., inductors) and reduce the effects of redundancy and leakage losses, multiinput energy harvesters have been designed with a single inductor boost converter [16,17,[19][20][21][22]. Figure 1a shows a block diagram of a multiinput single inductor (MISI) energy harvesting architecture.…”

“…one energy source is exploited over one switching cycle [16,17,19,21,22], or simultaneously, i.e. two energy sources can be utilized over one switching cycle [20] via switches. However, these switches require a supply power to turn on/off to create a bridge between the energy transducers and the converter to power the load.…”

“…Due to the relatively low voltages generated at energy transducers' outputs [1,5,15,21,30], the output of these energy transducers is insufficient to turn switches M1-Mn on/off, as the threshold voltage of the standard CMOS technology is typically higher than the energy transducer output voltage. Therefore, in order to provide initial operation for a short time, M1-Mn switches in MISI architectures are powered by a battery [16,17,20,21].…”

“…Thus, driving a WSN application through a power converter via a single energy source (e.g., PV) might not be an effective solution to best exploit the energy harvesting. For this reason, efforts to combine and utilize multiple energy sources are gaining popularity among energy harvesting researchers [12][13][14][15][16][17][18][19][20][21][22][23]. By combining multiple energy sources of the same or different types for flexibility, redundancy, or capacity [24], it is possible to improve system reliability [12, 16-19, 21, 23], achieve robustness against power failures [14,15], and increase the overall output power [12][13][14][15][16][17][18][19][20][21][22][23][24].…”

A fully batteryless multiinput single inductor single output energy harvesting architecture

A maximum power-point tracking multiple-input thermal energy harvesting module

An internal-resistance-adaptive MPPT circuit for energy harvesting