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A. Somà et alii, Frattura ed Integrità Strutturale, 23 (2013) 94-102; DOI: 10.3221/IGF-ESIS.23.10                                                                            
 

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Scilla 2012 - The Italian research on smart materials and MEMS 

 
  
Electro-mechanical coupled design of self-powered sensing  
systems and performances comparison through experiments  
 
 
A. Somà,  G. De Pasquale 
Department of Mechanical and Aerospace Engineering, Politecnico di Torino 
Corso Duca degli Abruzzi 24, 10129 Torino (Italy) 
aurelio.soma@polito.it, giorgio.depasquale@polito.it 
 

 
ABSTRACT. Recent advances in low-power sensors and electronic components open to innovative strategies in 
structural monitoring and real-time data processing, in particular for industrial and vehicular fields. Dedicated 
devices for harvesting the energy dissipated by mechanical vibrations of machines are showing their applicability 
in supplying autonomous distributed sensing systems. The harvester will replace cables and storage batteries, 
with relevant benefits on the sensing system capillarity, accessibility and applicability. The design of the 
interfaces of the electric, magnetic and structural coupled systems forming the harvester include static and 
dynamic modeling and simulation of the interactions involved; smart and effective architectures are need to 
satisfy the general requirements of bandwidth, tunability and efficiency required by each application. This paper 
reports the research advances in this field as a result of laboratory tests and design studies, with particular focus 
on the design methodologies involved in the definition of energy harvesters. 
 
KEYWORDS. Energy harvesting; Structural monitoring; Autonomous sensing; Bandwidth; Resonance tuning; 
Duty cycle; Efficiency. 
 
 
 
INTRODUCTION 
 

here are many unexploited energy sources in the environment such as light, wind, temperature gradients, 
radiofrequency waves, kinetic energy of sea waves, mechanical vibrations, human body motion, etc. The 
conversion of the unused energy in electricity, called ‘energy harvesting’, is motivating many academic and 

industrial researches in the last years [1-3]. Due to the small power amount that is usually available, the energy harvesting 
is mainly addressed to the supply of low consumption technologies. The harvesting of energy from the environment 
represents a valid alternative to batteries and cables, and promises to open new chances of development for mobile and 
wireless devices. Energy harvesters will allow using, for example, wireless sensors in many applications such as industrial 
and structural monitoring, remote medical assistance, military equipments, materials flows monitoring, transports and 
logistics, energetic efficiency control. Without the capabilities of energy harvesting devices, it is almost impossible to 
supply sensing devices in critical positions where accessibility is limited, for example in telemedicine applications and 
biological parameters monitoring. Miniaturized and wearable harvesters allow continuous monitoring of patients affected 
by chronic pathologies by means of sensors integrated in the body that do not need batteries for the supply of energy.  
This study compares some different strategies for harvesting energy from the environment, with particular attention to 
mechanical vibrations. In previous works, the authors analyzed the performances of different energy harvesters: 
piezoelectric [4], magnetic inductive [5], electrostatic capacitive, and magnetically levitated [6]. Also they patented some 
dedicated devices [7-9]. In this paper, the results of simulation and testing of different energy harvesters are introduced 
and compared in terms of energy generated per unit volume. Then, some design solutions for the integration of the 
harvester in monitoring devices for vehicles and mechanical systems are analyzed. Finally, after the comparison of 

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different conversion strategies, two typologies of harvesters are characterized for obtaining design indications about the 
autonomous sensing system. 
 
 
VIBRATING ENERGY CONVERSION STRATEGIES 
 

he kinetic energy associated to environmental vibrations is generally exploited by harvesters to excite the 
oscillation of a seismic inertial mass connected to the transducer. The motion induced on the seismic mass is 
regulated in amplitude, frequency and phase angle in order to maximize the conversion efficiency. The most 

diffuse conversion principles are piezoelectric, magnetic-inductive and capacitive (Tab. 1). In the following, the most 
important characteristics of these three conversion strategies are discussed. 

 
 

ENVIRONMENT ENERGY SOURCES

MAGNETIC INDUCTIVE 
ENERGY HARVESTING  

KINETIC ENERGY AND 
MECHANICAL 
VIBRATIONS 

CURRENT INDUCED BY 
MAGNETIC FIELD 

PIEZOELECTRIC 
ENERGY HARVESTING 

KINETIC ENERGY AND 
MECHANICAL 
VIBRATIONS 

DEFORMATION OF 
PIEZOELECTRIC 
MATERIALS 

CAPACITIVE  
ENERGY HARVESTING 

PRE‐CHARGED 
VARIABLE 

CAPACITORS  

ARMATURES
RELATIVE 

DISPLACEMENT  

THERMOELECTRIC 
ENERGY HARVESTING 

SEMICONDUCTORS 
TECHNOLOGY 

THERMALLY INDUCED 
ELECTRIC VOLTAGE 

SOLAR ENERGY 
HARVESTING  

PHOTOVOLTAIC  
CELLS 

CHARGES 
SEPARATION IN P‐N 

JUNCTIONS 

CONTROL ELECTRONICS

BATTERY  
 

Table 1: Some typologies of energy harvesters. 
 

Piezoelectric energy harvesters 
In this typology of generators, the seismic mass induces the deformation of a piezoelectric component that produces a 
voltage difference between its electrodes proportional to the mechanical strain. About piezo generators, some reliability 
limitations have been pointed out in the literature because of the brittleness of materials used (PZT, PVDF, etc). The 
electric output power is function of the resistive load applied to the transducer; then, the preliminary characterization of 
the impedance of the electronic conditioning circuit is needed. The shape of the output signal under sinusoidal excitation 
represents another possible source of inefficiency; in fact, current and voltage waves are slightly phase shifted due to the 
intrinsic capacitance of the piezoelectric material. This reduces the effective output power with respect to the optimized 
output power theoretically available in case of preliminary phase synchronization of current and voltage; unfortunately this 
operation needs relevant complications of the conditioning circuit and is generally omitted. Usually, the output voltage is 
rather high (in the order of tens of V), while the current is generally low (in the order of mA); when the storage battery is 
included in the autonomous sensing system, the voltage/current ratio should be modified in order to reduce the time of 
charge. This operation also requires additional circuit complications.  
The advantages related to piezoelectric generators are given by the large commercial availability of transducers, which are 
almost ready for the integration in the harvesting system. Furthermore, they are characterized by good ratios of generated 
power per unit volume. From the dynamic viewpoint, these typology of generators can be applied to moderately wide 
ranges of frequencies (up to few hundreds of Hz), which are typically associated to structural vibrations. The resonance 
tuning can be achieved by varying the stiffness of the deformable element or by changing the seismic mass. Instead, the 
active tuning able to set the resonance on the actual working regime and bandwidth is generally more complicated. An 
example of piezoelectric generator is reported in Fig. 1. 
 

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Figure 1: Piezoelectric generator [10]: 10x10x1mm3 size, 60μW output power in resonance condition (572 Hz) and 2g acceleration. 
 
Magnetic inductive energy harvesters 
In this case, the vibrating energy is used to induce the relative motion between a permanent magnet and a conductive coil. 
In the literature, a number of design solutions have been introduced, which include fixed magnet and movable coil or, 
more frequently, fixed coil and movable magnet. The design activity involves the selection of the coil diameter and turns 
number, which are both related to the current produced and to the electric resistance of the wire. By varying these two 
parameters, the optimized solution can be found in terms of conversion efficiency. Other important design parameters are 
the magnetic material and the magnet dimensions. Generally, magnets characterized by high induced magnetic field are 
preferable, as the so-called ‘rare earths’ magnets (e.g. NdFeB). The most important benefits in using inductive harvesters 
are the stability of performances, the high reliability and, above all, the high current/voltage ratio that makes these 
generators suitable for charging batteries without complicated electronic conditioning. Unfortunately, the integration of 
tuning controls is generally hard because the resonance of the harvester is dominated by the mass properties of the 
magnet, which is already dimensioned to fit the electric requirements. Furthermore, the power generation is strongly 
linked to the magnet velocity, with reference to the relation between the current induced in the coil and the gradient of the 
magnetic field expressed by the Faraday law. This indicates that high output power is obtainable from long travels of the 
magnet and, consequently, by dedicated design of suspensions. The lowering of suspension stiffness can be obtained, for 
instance, by using magnetic springs represented by repulsing magnets. Fig. 2 reports an example of inductive energy 
harvester from the literature. 
 

 
 

Figure 2: Magnetic-inductive energy harvester [11]: 54x46x15mm3 size, 0.55mW output power at 9.25Hz frequency and 0.8g 
acceleration. 
 
Capacitive energy harvesters 
Capacitive generators are basically capacitors with movable armatures where the relative displacement of the armatures is 
induced by external vibration and is used to generate voltage or charge difference between them. The electric power 
generated is strongly dependent to the capacitor geometry: in particular, small gaps between armatures and large armature 
surfaces are particularly advantageous. However, the pre-charge of armatures is needed to generate energy and it 
represents serious limitation to the efficiency of the energy harvester. In order to reduce as much as possible the charging 
energy, very small armatures surfaces are preferred. Then, in practice, the application of capacitive energy harvesters is 
limited to small scales and some examples are available in the field of MEMS (micro electro-mechanical systems). The 

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mentioned properties represent the most relevant drawbacks of capacitive generators; another limitation is given by the 
high dynamic response of the harvester that is imposed by the small masses used, which reduces the applicability of these 
devices to high frequencies (in the order of kHz). 
However, in the microscale, the technology required to fabricate this typology of devices (i.e. surface micromachining) is 
consolidated and good constructive solutions are achievable. Recently, it was documented the possibility to apply 
particular materials (electrets) on the variable capacitor surfaces; these materials have intrinsic charge and they are able to 
preserve this charge for long time compared to the harvester life. This technological improvement makes unnecessary the 
electric preload and sensitively increases the device efficiency. Fig. 3 reports an example to MEMS capacitive harvesters 
and a harvester with electret. 
 

  
 

(a) (b) 
 

Figure 3: (a) Capacitive generator [12] including the seismic mass represented by a tungsten ball (4mm diameter) for the frequency 
tuning at 120Hz (31μW output power at 0.23g). (b) Capacitive generator with electret [13] (1μW output power at 63Hz and 2g). 
 
 
POWER SPECTRAL DENSITY, FREQUENCY TUNING AND BANDWIDTH AMPLIFICATION 
 

rom the methodological viewpoint, the preliminary analysis of the vibrating excitation source is needed before to 
dimension the harvester. In general applications, the input force has random shape because it is produced by 
machines or mechanical systems having variable operating regimes (e.g., vehicles in motion at different velocities 

or aircrafts in different flight conditions). The average energy associated to the input signal can be evaluated, for instance, 
from the acceleration associated to every specific working condition or, more generally, from the overall acceleration 
range. After estimating the available energy, then is possible to define, at least roughly, the size of the harvester and the 
size of the oscillating parts. The goal of this first design tentative is to provide the order of magnitude of masses and 
suspensions stiffness with reference to the response/excitation amplitude ratio. In other words, the dynamic parameters 
of the generator are defined in dependence to the desired FRF.  
Next step addresses to the analysis of energy distribution in the frequency spectrum. Usually, the environmental 
oscillation is amplified in correspondence to particular frequencies because of multiple resonances and combined modal 
couplings that interest the machine or mechanical system hosting the harvester. In correspondence to the machine 
resonance, the available energy coming from the vibrating environment is amplified. The description of the energy 
distribution in the frequency domain is provided by the PSD (power spectral density) function that must be considered 
accurately during the next part of the dimensioning. 
The harvester tuning consists in modifying the mass and stiffness parameters that have been approximately defined in the 
very preliminary dimensioning. The dynamic parameters are finalized in detail at this stage; generally, their values are 
constant for the overall generator life: this is the simpler approach that well fits environments characterized by regular 
vibrations and repeatable PDS. However sometimes the working regimes are strongly variable and the energy amount 
associated to vibrations is very scarce; in these cases, the adoption of active tuning systems able to change the dynamic 

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response of the generator is needed. Unfortunately, active tuning systems generally cause additional power consumption 
and intense optimization activities are required to preserve acceptable values of efficiency. Tuning systems with fixed 
response are, for example, arrays of vibrating structures with slightly variable geometry, stiffness variation by preloading, 
additional masses, etc. Tuning systems providing variable response to the harvester are, for example, movable constraints, 
movable masses, variable external forces (e.g. magnetically induced), etc. 
 

Mass 2Mass 1 Mass 3

K₁₂ K₂₃

 
 

 
Figure 4: Example of design strategy for amplifying the bandwidth of a capacitive generator through the coupling of 
modal shapes. 
 
Another important parameter for the generator is the bandwidth. From the dynamic viewpoint, vibration harvesters 
behave like mechanical filters: the excitation signal induces the movement of the oscillating system according to its 
dynamic behavior. The harvester response is directly proportional to the generated energy, because the dynamic response 
drives the electro-mechanical transducer, independently to the typology. Obviously, wide band generators are more 
performing than narrow band generators because the first ones are able to catch the energy associated to external forces in 
larger frequency ranges. In case of high variability of the excitation force, corresponding to very distributed PSD, wide 
band harvesters are more suitable. There are many strategies to amplify the bandwidth; the most diffused are the modal 
coupling of many transducers (Fig. 4), the series coupling of multiple generators, and the use of bi-stable structures. 
 
 
SYSTEM ARCHITECTURE AND DUTY CYCLE 
 

he activity of design and dimensioning of the generator must be supported by the detailed information about the 
characteristics of the overall autonomous system including its performances, sampling rate, frequency of data 
transmission, etc. For this reason, the best definition of this step of activity is ‘self-powered system design’ instead 

of simply ‘energy harvester design’; in fact, the definition includes also the electrical parameters of the utilizer and the 
device performances. Although the typology of components included in the autonomous system may vary among the 
applications, usually the following functional blocks can be identified (Fig. 5): current rectifier, charge reservoir (storage 
battery), one or more sensing devices (sensors), and transceiver device. Very frequently the energy generated by the 
harvester is stored in the battery before to be used; this operation requires the preliminary conversion of the alternate 
current produced by the harvester in continuous current. The charge storing, is an expensive activity in terms of energetic 
efficiency, however it is often necessary due to some reasons: firstly, to provide continuous supply also in case of irregular 
power supply; secondly, to reach the prescribed energy threshold needed to supply the utilizer. 
The energy produced by the harvester and stored in the battery can be used for the supplying only when the minimum 
charge threshold is reached; this lower level of the battery charge is imposed by the energetic demand of the utilizers. 
Similarly, the time interval when the power flows from the battery to the utilizer must be calculated in function to the 

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energy consumed in the unit time. The constraints mentioned are well considered in defining the duty cycle of the self-
powered system. The adoption of dedicated strategies addressed to the reduction of the energy consumption is vital for 
the proper working of the system; for instance, power management operations should be implemented, which consists in 
activating the system only above specified charge threshold of the battery (triggering) or in switching-off some 
components (e.g. the antenna) during data measurement and processing. 
 

 
 

Figure 5: Typical architecture of self-powered sensing system. 
 
 
EXPERIMENTAL COMPARISON OF PERFORMANCES 
 

his section reports the experimental characterization of the performances of two typologies of energy harvesters: 
piezoelectric and magnetic inductive. The generators are tuned during the tests by modifying their resonance 
through additional masses or by changing the stiffness of the deformable parts. Different values of the input 

acceleration are imposed, in order to verify the variation of the electro-mechanical response. The measurements were 
conducted by using the dedicated test equipments described in the following. 
 
Test bench 
The test bench for the experimental tests is composed by the parts reported in the following scheme (Fig. 6). 
 

 
 

Figure 6: Blocks diagram of the test bench for the experimental characterization of the harvesters. 
 
Piezoelectric generators 
Two types of piezoelectric generators are reported in Fig. 7. The first generator is commercialized by Cedrat Technologies 
for applications in the aeronautic field [14], the second generator is a laboratory prototype fabricated for harvesting energy 
from railway vehicles and integrates the transducer DuraAct P-876.A12 [4]. Their principal characteristics are summarized 
in Tab. 2. 
The commercial harvester is composed by two piezoelectric blocks situated within a metallic frame that, under vibrations 
applies the tensile-compressive load to the electro-mechanical transducer according to modal deformation. The selected 
design gives high stiffness to the structure (100 N/mm nominal) and increases the resonance frequency up to about 400 
Hz. The laboratory prototype, instead, is based on the deformation of the piezoelectric cantilever in the flexural mode: 
this configuration allows maximizing the ratio between the material strain and the applied force. Then, the harvester 
stiffness can be reduced to only 0.06 N/mm and the resonance frequency is lowered to about 27 Hz. The drawbacks of 

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the second solution are mainly related to the reduced reliability of the transducer, which is made of brittle material 
subjected to fatigue effect. However, the polymeric package that coats the piezo surface of the commercial transducer 
provides sensitive improvements to the component lifetime (longer than 106 cycles with 1 g acceleration). 

 

 Cedrat generator Laboratory prototype 

Dimensions (mm) 48x13x10 60x35x0.5 
Capacity (nF) 3150 90-150 

Optimized load (kΩ) 0.47 200 
Resonance frequency (Hz) 405 27 

 

Table 2: Some properties of the two piezoelectric generators. 
 

  
 

(a) (b) 
Figure 7: (a) Piezoelectric generator working in tension-compression VEH-APA 400M-MD (Cedrat Technologies); (b) laboratory 
prototype of flexural generator made with DuraAct P-876.A12 transducer. 
 
The preliminary characterization of the generator, which is mandatory for piezoelectric harvesters, is addressed to the 
identification of the optimum resistive load associated to the transducer. For this type of generators, the output power is 
function of the electric resistance connected in series to the generator. The electric resistance is partially provided by the 
conditioning electronics, the rectification circuit and other electronic components. The characterization revealed that the 
commercial transducer has the optimum load at 0.47 kΩ and the laboratory prototype at 200 kΩ.  
Fig. 8 reports the power curves referred to the generators. Different masses were applied to the metallic frame in the first 
case and to the cantilever tip in the second case to modify the harvester response. In Fig. 8a it is clearly visible the shift of 
the resonance peak due to the mass change; this strategy is suitable for tuning the resonance of the generator on different 
values of the excitation frequency. In Fig. 8b, the ratio seismic mass/deformation is sensitive to the transducer 
configuration for constant input acceleration. In this case, all measurements are referred to the system resonance.  
 

  
 

(a) (b) 
 

Figure 8: Output power generated by commercial harvester as function of the excitation frequency (a) and by laboratory prototype as 
function of the resistive load in resonance conditions (27 Hz) for variable seismic mass (b). 

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Magnetic inductive generators 
The schematic drawing of the magnetic inductive energy harvester designed and built by the authors in [5] is represented 
in Fig. 9. For this type of generators, the selection of materials and dimensions of components is crucial for the electric 
output power and for the system frequency tuning. The magnetic suspension representing the stiffness of the transducer 
is determined by the magnetic field intensity associated to the magnets with opposite polarity; similarly, the electric current 
induced in the coil is proportional to the size of the oscillating magnet and to its relative velocity, which are both 
dependent to the suspension stiffness. In conclusion, the dimensioning is significantly complicated by the strong electro-
mechanical coupling among the components and by the variability of frequency and acceleration of the excitation 
resulting from its spectrum. 

 
 

Figure 9: Schematic drawing of the magnetic inductive harvester prototype [5]. 
 
Analytical models and numerical models based on finite element method were used to calculate the force-displacement 
characteristic of the magnetic suspension. The goal of experimental tests is to find characteristic curves suitable for the 
design in specific functioning conditions. Some of the tests results are described in Fig. 10; these curves are referred to a 
prototype composed by oscillating magnet on magnetic suspension, 4 coils connected in parallel and current rectifier. The 
resonance frequency of the harvester is 3.2 Hz and the tests are conducted at 0.12 g acceleration. 
This particular typology of inductive generator has been addressed to applications in railway bogies [7], axels of industrial 
vehicles [9], telescopic arms, operative machines and sport equipment [8], where the excitation frequency range is localized 
at low values. 
 

(a) (b) 
 

Figure 10: Electric output of the magnetic inductive generator with 4 coils (3.2 Hz, 0.12 g): (a) current and voltage and (b) output 
power. 

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CONCLUSIONS 
 

his work introduced the most important steps of the design autonomous systems for converting the kinetic energy 
of mechanical vibrations in electric power. The activity is focused on the self-powered sensing system design, 
instead of traditional simpler energy harvester design, with the aim of responding more exhaustively to the 

requirements of the application. From the energetic balance viewpoint, the concept of duty cycle is crucial, as well as the 
analysis of input vibration spectra through its PSD and its time-dependent variability. These aspects, together with 
bandwidth amplification strategies and resonance tuning, provide the required information for selecting the proper 
transducer typology and for defining its dimension and dynamic properties. 
 
 
REFERENCES 
 
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[3] S. Priya, D.J. Inman, “Energy harvesting technologies”, New York, Springer (2008). 
[4] G. De Pasquale, A. Somà, F. Fraccarollo, In: Proceedings of the Institution of Mechanical Engineers - Part C: Journal 

of Mechanical Engineering Science, 226 (2011). 
[5] G. De Pasquale, A. Somà, N. Zampieri, J. of Computational and Nonlinear Dynamics, 7 (2012) 041011. 
[6] G. De Pasquale, C. Siyambalapitiya, A. Somà, J. Wang, In: Proc. International Conference on Electromagnetics in 

Advanced Applications (ICEAA), Torino 465-468,  (2009). 
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