Post on 19-May-2020
ELECTRONICS, PHOTONICS AND MICROSYSTEMS Andrzej DZIEDZIC, Piotr MARKOWSKI Autonomous Power Supplying Systems
Autonomous Power Supplying Systems – course description • Energy sources from circuit theory point of view
• Examples of practical power supply units
• Thermoelectric phenomena, methods of characterization of thermoelectric materials and devices
• Modern thermoelectric materials and devices – fabrication and properties
• Peltier modules
• Application of thermoelectric modules in sensorics (examples)
• Photovoltaic effect, solar cells
• Technological and constructional solutions and exploitation parameters of solar microcells and micromodules
Basic literature (1) • J. Rutkowski, Circuit Theory, Publ. House of Silesian Univ. of Technology,
Gliwice 2006
• J. Osiowski, J. Szabatin, Podstawy teorii obwodów, tom I, WNT, Warszawa, 1998
• CRC Handbook of Thermoelectrics, ed. by D.M. Rowe, London, CRC Press 1996
• Thermoelectrics Handbook – Macro to Nano, ed. by D.M. Rowe, Taylor and Francis, 2006
• T.M. Berlicki, Warstwowe czujniki termoelektryczne, Of. Wyd. Pol. Wrocławskiej, 2007
• H.J. Goldsmid, Introduction to Thermoelectricity, Springer, 2009
• Energy Harvesting Technologies, ed. By S. Priya and D.J. Inman, Springer 2009
Basic literature (2) • A. Luque, S. Hegedus, Handbook of Photovoltaic Science and Engineering,
John Willey and Sons, 2003
• Papers from the following journals: Sensor Review, Sensors and Actuators A: Physical, Microsystem Technology, Measurement Science and Technology, Microelectronics Journal, Microelectronics Reliability, Materials Science and Engineering A, Journal of Applied Physics, Journal of Microelectromechanical Systems, Journal of Materials Science, Renewable Energy, Sensor Journal, Journal of Micromech. Microeng. , Review of Scientific Instruments, Thin Solid Films, Physical Review B, Progress in Photovoltaics: Research and Applications, Applied Physics Letters, Solar Energy Materials and Solar Cells, IEEE Transactions on Electron Devices, Journal of Electronic Materials
Basic literature (3) • Papers from the following conferences: IMAPS US, IMAPS Europe, IMAPS
Poland, Int. Conf. on Thermoelectrics, Eur. Conf. on Thermoelectrics, Smart System Integration, Eur. Photovoltaic Solar Energy Conf., IEEE Photovoltaic Specialist Conf., World Conference on Photovoltaic Energy Conversion
• Web pages – eg. http://pl.wikipedia.org , http://www.epia.org , http://solarwirtschaft.de , http://www.solarworld.de ,
Topic 1. Introduction into autonomous power supplying systems and analysis of energy sources from circuit theory point of view
1. Kinds of autonomous power sources
2. Ideal and real current and voltage sources
3. Equivalence of sources
4. Connections of ideal and real current or voltage sources
5. Dependent (controlled) sources
6. DC analysis – source-load single loop circuits
7. AC steady-state analysis
Microcircuit powering
”Traditional” autonomous power sources
System U [V]
P [μW]
microcontroller MSP 430
2.2 5
microcontroller ATmega88V
1.8 27
microcontroller ATtiny13V
1.8 45
Intelligent sensor node MICA2
2.7 216
stand-by
Different kinds of power sources
Generator Density of output power
Remarks DS [mW/cm2]
DV [mW/cm3]
Galvanic cells (batteries)
0.003 0.8 Working time – about 1000 hours – a few thousand of cycles
Electromagnetic coupling
8 0.8
Distance – a few mm
Fuel cells 5 26 Working time – about 1000 hours
Inertial generators (inductive)
0.8 0.6 For resonance frequency
Inertial generators (piezoelectric)
0.03 0.07
Photovoltaic cells 0.4 10 Strong dependence on irradiance
Thermoelectric microgenerators
0.05 0.2
For ΔT = 10C
Schematic of the architecture required for self-powered wireless sensor network to achieve desired reliability for
long period time
Self-adaptive Intelligent
Energy Harvesting
Management System
Piezoelectric energy
harvesting
Thermoelectric energy
harvesting
Solar energy
harvesting
Micro-battery Energy Storage
Ultracapacitor / Multilayer caps Energy Storage
Circuit theory – current and voltage sources
U U
I
I
A B
D C
Receiver of
electrical
energy
Non- electrical energy
Non- electrical energy
Active part of circuit
Passive part of circuit
Source of
electrical
energy
Active two-terminal elements Ideal voltage source (electromotive force)
U
I
E
E +
U
I
E
+ −
U
I
E
a) Some of graphic symbols b) I-U relationship of ideal voltage source
−
Active two-terminal elements Ideal current source
a) Some of graphic symbols b) I-U relationship of ideal current source
U
I
J
U
I
J
J
I
U
+
− J
U
I J
Active two-terminal elements Practical (real) voltage source (1)
U
I
E
RS(Ri)
I
RS RS(Ri) – source (internal) resistance +
-
Active two-terminal elements Practical (real) voltage source (2)
I-U relationship of practical voltage source (E – open-circuit voltage, IS = E/RS – short-circuit current)
U
I
E
U
I
E
IS
U = E − I·RS
Active two-terminal elements Practical (real) current source (1)
SS R
1G
U J GS(Gi)
GS(Gi) – source (internal) conductance
Active two-terminal elements Practical (real) current source (2)
I-U relationship of practical current source
U
I J
U
I
J·RS
J
UR
1J
UGJI
S
S
Equivalence of sources
E
RS
J GS
SS
SS
GJRJE
GEREJ
SS R
1G
Series connection of ideal voltage sources
n
ne EE
En
E1
Ee
Parallel connection is unachievable
Parallel connection of ideal current sources
J1 Jk Je k
ke JJ
Series connection is unachievable
Series connection of practical (real) voltage sources
n
SnSe
n
ne
RR
EE
E1
RS1
En
RSn
Ee
RSe
Parallel connection of practical (real) current sources
k
ke JJ
k
skse GG
J1 GS1 J1 GSn Je GSe
Parallel connection of practical voltage sources
21
21
Se
S2S1
S12S21
Seee
RR
RRR
RR
RERERJE
E2
RS2
E1
RS1
J1 GS1 J2 GS2 Je GSe Ee
RSe
S2S1S2S1Se
S2
2
S1
121e
R1
R1GGG
RE
RE
JJJ
Series connection of practical current sources
S2S1
S2S1Se
S2S1
S12S21
Se
ee
GG
GGG
GG
GJGJ
R
EJ
S2S1Se
S2
2
S1
1e
RRR
G
J
G
JE
Je GSe
Ee
RSe
E2
RS2
E1
RS1
J1 GS1
J2 GS2
I IS1
IS2
E1 = J1/GS1
E2 = J2/GS2
Parallel connection of practical and ideal voltage sources
0R0
R0R
ER0
0EREE
2
2
Se
1
S2
2S21
e
Ee
RSe E2 RS2 E1
RS1 = 0
Series connection of practical and ideal voltage sources
2
n
SnSe
21
n
ne
RRR
EEEE
E1
E2
R2
Ee
RSe
Series connection of practical and ideal current sources
0GG
GG
R
1G
JGG
GJGJJ
S2S1
S2S1
Se
Se
1
S2S1
S12S21e
J2 GS2
J1
GS1 = 0
Je GSe
Parallel connection of practical and ideal current sources
21
k
ke JJJJ
2
k
skse GGG
J1 J2 G2 Je GSe
Dependent (controlled) elements A controlled elements is described by the following relationships:
I = f(U,X) or U = g(I,X)
Such element is described by a family of I-U characteristics, with X as the second parameter, so-called control variable, which can be temperature (T), lighting flux (Φ), other voltage (UC) or other current (IC)
Control source is a source that provides a current or voltage that is dependent on other current or voltage elsewhere in the circuit
Voltage controlled sources
V
VkUE
a) Voltage controlled voltage source (VCVS)
Family of I-U relationship characterizing VCVS
control coefficient
U
I
kUC3 UC3
kUC2 UC2
kUC1 UC1
kUC4 UC4
E=kUEUC UC + -
Voltage controlled sources
b) Voltage controlled current source (VCCS)
SV
AkUJ
transconductance [Siemens]
J=kUJUC
UC
Current controlled sources c) Current controlled current source (CCCS)
Family of I-U relationship characterizing CCCS
A
AkIJ
control coefficient
U
I
IC3 IC2
kIC1
IC1 IC4
kIC2 kIC3 kIC4
J=kIJIC IC
Current controlled sources d) Current controlled voltage source (CCVS)
Ωi .e.A
VkIE
transresistance E=kIEUC
+ -
IC
DC analysis – source-load single loop circuits
E
RS RL
I
U
SOURCE LOAD
RL
I
U
SOURCE LOAD
J
GS or RS
AC steady-state analysis
E(jω)
ZS(jω) ZL(jω)
I(jω)
U(jω)
SOURCE LOAD
jωexpZjXR
jωZjImjωZRejωZ
R
XarctgXRZ 22
sinZXcosZR
AC steady-state analysis
jωY
1LjjωZ
jωY
1
Cj
1jωZ
jωY
1RjωZ
Transformation Wye – Delta (Y Δ)
Ra
Ea
Rc Ec
Eb Rb
A
C B
Rab
Eab
Rac
Eac
Ebc Rbc
A
C B cbbc
caac
baab
EEE
EEE
EEE
a
cbcababc
b
cbcabaac
c
cbcabaab
R
RRRRRRR
R
RRRRRRR
R
RRRRRRR