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LSU 11/05/2013 Electronics 5 1
Power SourcesElectronics Unit – Lecture 5
Bench power supply
Photovoltaic cells, i.e., solar panel
Thermoelectric generator
Battery
Power Budget
LSU 11/05/2013 Electronics 5 2
Bench Power Supply
Adjustable, regulated output voltage
Often includes a current limiting feature
Great for designing and prototype testing
Not for flight
LSU 11/05/2013 Electronics 5 3
Bench Power Supply
Important specifications:
Voltage range - should be 0 V to ~12 to 15 V
Load current - should be a few hundred mA
Regulation - hold output with a few tenths of V
Current limiting - very desirable if adjustable
can protect circuits from accidental damage
LSU 11/05/2013 Electronics 5 4
Photovoltaic panel
Potential flight power source
“Free” electricity while Sun shines
Size and weight concerns
Expense
LSU 11/05/2013 Electronics 5 5
Photovoltaic panelPanels made up of an array of individual cells
Each cell produces about 0.5 volt potential
Cell current depends on surface area and illumination
In full sun expect perhaps 10 milliwatts per cm2
For 6 V at 100 mA (600 mW) 12 cells would be needed, each having surface area about 5 cm2
Must face the Sun - and payload is probably rotating
Multiple panels needed - unless auto pointing
LSU 11/05/2013 Electronics 5 6
Photovoltaic panelCells are delicate and subject to breakage
Voltage output may vary - electronic regulation needed
Backup battery needed for cloudy intervals
Not the best choice for short duration student flights
LSU 11/05/2013 Electronics 5 7
ATIC
LSU 11/05/2013 Electronics 5 8
Thermoelectric GeneratorUses the Seebeck Effect to convert a temperature difference directly into an electric current
Needs a heat source - deep space missions use the heat of radioactively decaying plutonium
Probably not a good choice for a student project ☺
LSU 11/05/2013 Electronics 5 9
Battery
Strictly, a battery is a combination of discrete cells
Best choice for short duration flights
Inexpensive
Reasonably lightweight
Variety of voltages and energy capacities available
LSU 11/05/2013 Electronics 5 10
Battery TypesPrimary batteries - one time use
carbon-zinc (old fashioned flashlight batteries)
alkaline (most common in consumer products)
silver-mercury (used in hearing aids and older cameras)
lithium - lots of energy for small weight
Rechargeable batteries - multiple charges/dischargeslead-acid (car batteries, or “gel cells”)
nickel-cadmium, Ni-Cd (older style rechargeable chemistry)
nickel-metal hydride, NiMH (popular now in consumer products)
lithium ion, (high end uses - laptop computers, digital cameras)
LSU 11/05/2013 Electronics 5 11
Battery Characteristics
Terminal voltage - depends on specific chemistry
Capacity - rated in ampere-hours, or milliampere-hours3600*(ampere-hours)*(average terminal voltage) = energy capacity in joules
Physical size and weight - energy density in joule/gram
Discharge characteristics - especially at low temperature
LSU 11/05/2013 Electronics 5 12
Battery Characteristics
Terminal voltage - depends on specific chemistry
carbon-zinc about 1.5 V per cell
alkaline - about 1.5 V per cell
lead acid - about 2.0 V per cell
Ni-Cd and NiMH - about 1.2 V per cell
lithium - about 1.5 V per cell
but often made as double-cells for 3 V
LSU 11/05/2013 Electronics 5 13
Battery Characteristics
Capacity - rated in A-hr or mA-hr for small cells
Usually specified at the “ten-hour discharge rate”
Example - an Energizer AA 1.5 V lithium cell rated 2900 mA-hr
should deliver 290 mA for 10 hr before voltage falls below 1V
But, will not last proportionally as long at higher currents
LSU 11/05/2013 Electronics 5 14
Battery CharacteristicsDischarge characteristics - the discharge curve
Use this typical lithium battery as an example
Nominal Voltage 3.0V
Rated Capacity 5Ah to 2.0V at 20°C (68 F)
Average Weight 55g (1.94oz)
Volume 26.5cm3 (1.60in.3)
Operating Temp. Range -20°C to 60°C (-4 F to 140 F)
LSU 11/05/2013 Electronics 5 15
Battery Characteristics
Notice the degradation of capacity at low temperatures, especially at higher load currents.
And lithiums are about the best!
LSU 11/05/2013 Electronics 5 16
Calculating a Power Budget
Given: minimum permissible voltage
maximum load current
average off-peak load current
load current versus time data (duty cycle)
mission duration
minimum expected temperature
LSU 11/05/2013 Electronics 5 17
Power Budget Example
The GPS radio telemetry package:Transmitter requires a minimum supply voltage of 9 VGPS receiver requires from 3 V to 6 VFlight computer requires 5 V
If a single battery pack powers all three units, its terminal voltage cannot fall below 9 V.
Voltage regulators will be used to reduce the voltage for the other units.
LSU 11/05/2013 Electronics 5 18
Power Budget Example
The GPS radio telemetry package:
GPS receiver draws 140 mA, continuously (100% duty)
Flight computer draws 50 mA, continuously (100% duty)
Transmitter draws 80 mA when in standby mode (93% duty)
Transmitter draws 1050 mA when transmitting (7% duty)(since transmitter sends a 2 second data burst every 30 seconds)
Peak current = 1320 mA, minimum current = 270 mA
LSU 11/05/2013 Electronics 5 19
Power Budget ExampleThe GPS radio telemetry package:
GPS: 140 mA x 1 = 140 mA
Flight Computer: 0 mA x 1 = 50 mA
Radio Standby : 80 mA x 0.93 = 75 mA
Radio Transmit: 1050 mA x 0.07 = 74 mA
Add them up….. about 340 mA
If the beacon must operate for at least 8 hours…
340 mA x 8 hours = 2720 mA-hr required from the battery pack
LSU 11/05/2013 Electronics 5 20
Power Budget Example
The GPS radio telemetry package:
A sufficient number of cells must be wired in series so that, even when delivering 1320 mA, the composite terminal voltage remains above 9 V, even at the minimum expected temperature.
Consulting the battery curves previously viewed, cell voltage can drop to about 2.2 V at -20 celsius when delivering 600 mA or more. Therefore, four cells will be needed. Allowing a reserve, cells should have a capacity of about 3000 mA-hr.
LSU 11/05/2013 Electronics 5 21
Power Budget Example
Mission Duration Considerations
A science package must operate through pre-launch preparation and for the full duration of flight. If data is in non-volatile storage, it need not operate after touchdown. (~ 4 hours)
A tracking beacon must operate through pre-launch, the entire flight interval, and be able to continue well after touchdown to assure recovery. (8 hours or more)
LSU 11/05/2013 Electronics 5 22
Voltage Regulator IC
Fixed Voltage outputs available (3.3, 5, 9, 12, 15, etc.) Vout < Vin -
Voh Positive or Negative models available
(Check pinout!) Variable Voltage models – set with
resistor values. LM317 Low Dropout models have lower
overhead voltage Ratings: Voltage In/Out, Max Current
LSU 11/05/2013 Electronics 5 23
DC/DC Converter
Step-Up or Step-Down Voltage (or both) Uni-Polar, Bi-polar, or multiple Vout Specifications:
Voltage In (Min and Max) Voltage(s) Out Maximum Current, Maximum Power Out Efficiency: Pout = Pin*Efficiency
Mechanical (and Thermal) Packaging, connections Size and Weight
LSU 11/05/2013 Electronics 5 24
Power System Example
LSU 11/05/2013 Electronics 5 25
RegulatorsDC/DC Converters
LSU 11/05/2013 Electronics 5 26
RegulatorsDC-DC Converters
12V50 mA
75 mA
20 mA
50mA
75mA
24V*20mA = 480mW
480mW/0.80= 600mW
I=P/V so I=600mW/12V
I = 50 mA if efficiency = 80%
I total= 50mA+75mA+50mA=175mA
LSU 06/04/2007 Electronics 6 27
HOBO® Data Logger
Combines sensors, transducers, signal conditioning, A/D conversion, storage, and readout into a compact, battery powered unit.
LSU 06/04/2007 Electronics 6 28
DIY Data Logger
Sketch a System Diagram for a data logger that logs a timestamp, temperature and battery voltages of two different packs (to compare alkaline and lithium battery performance.)