LTC3108EDE#PBF Datasheet LTC3108IDE#PBF, LTC3108EDE#TRPBF, LTC3108EGN#PBF | P13-P15

LTC3108

3108fc

For more information www.linear.com/LTC3108

this manner, a Peltier cell is referred to as a thermoelectric

generator (TEG).

The low voltage capability of the LTC3108 design allows

it to operate from a TEG with temperature differentials

as low as 1°C, making it ideal for harvesting energy in

applications in which a temperature difference exists

between two surfaces or between a surface and the am

bient temperature. The internal resistance (ESR) of most

cells is in the range of 1Ω to 5Ω, allowing for reasonable

power transfer. The curves in Figure 2 show the open-

circuit output voltage and maximum power transfer for a

typical Peltier cell (with an ESR of 2Ω) over a 20°C range

of temperature differential.

TEG Load Matching

The LTC3108 was designed to present a minimum input

resistance (load) in the range of 2Ω to 10Ω, depending

on input voltage and transformer turns ratio (as shown

in the Typical Performance Characteristics curves). For

a given turns ratio, as the input voltage drops, the input

resistance increases. This feature allows the LTC3108 to

optimize power transfer from sources with a few ohms

of source resistance, such as a typical TEG. Note that a

lower source resistance will always provide more output

current capability by providing a higher input voltage

under load.

Peltier Cell (TEG) Suppliers

Peltier cells are available in a wide range of sizes and power

capabilities, from less than 10mm square to over 50mm

square. They are typically 2mm to 5mm in height. A list

of Peltier cell manufacturers is given in Table 3.

Table 3. Peltier Cell Manufacturers

CUI, Inc.

www.cui.com (Distributor)

Fujitaka

www.fujitaka.com/pub/peltier/english/thermoelectric_power.html

Ferrotec

www.ferrotec.com/products/thermal/modules

Kryotherm

www.kryothermusa.com

Laird Technologies

www.lairdtech.com

Marlow Industries

www.marlow.com

Micropelt

www.micropelt.com

Nextreme

www.nextreme.com

TE Technology

www.tetech.com/Peltier-Thermoelectric-Cooler-Modules.html

Tellurex

www.tellurex.com

applicaTions inForMaTion

Table 4. Recommended TEG Part Numbers by Size

MANUFACTURER 15mm × 15mm 20mm × 20mm 30mm × 30mm 40mm × 40mm

CUI Inc. (Distributor) CP60133 CP60233 CP60333 CP85438

Ferrotec 9501/031/030 B 9501/071/040 B 9500/097/090 B 9500/127/100 B

Fujitaka FPH13106NC FPH17106NC FPH17108AC FPH112708AC

Kryotherm TGM-127-1.0-0.8 LCB-127-1.4-1.15

Laird Technology PT6.7.F2.3030.W6 PT8.12.F2.4040.TA.W6

Marlow Industries RC3-8-01 RC6-6-01 RC12-8-01LS

Tellurex C2-15-0405 C2-20-0409 C2-30-1505 C2-40-1509

TE Technology TE-31-1.0-1.3 TE-31-1.4-1.15 TE-71-1.4-1.15 TE-127-1.4-1.05

LTC3108

3108fc

For more information www.linear.com/LTC3108

Thermopile Generator

Thermopile generators (also called powerpile generators)

are made up of a number of series-connected thermo

couples enclosed in a metal tube. They are commonly

used in gas burner applications to generate a DC output

of hundreds of millivolts when exposed to the high tem

perature of a ﬂame. Typical examples are the Honeywell

CQ200 and Q313. These devices have an internal series

resistance of less than 3Ω, and can generate as much as

750mV open-circuit at their highest rated temperature. For

applications in which the temperature rise is too high for

a solid-state thermoelectric device, a thermopile can be

used as an energy source to power the LTC3108. Because

of the higher output voltages possible with a thermopile

generator, a lower transformer turns ratio can be used

(typically 1:20, depending on the application).

Photovoltaic Cell

The LTC3108 converter can also operate from a single

photovoltaic cell (also known as a PV or solar cell) at light

levels too low for other low input voltage boost convert

ers to operate. However, many variables will affect the

performance in these applications. Light levels can vary

over several orders of magnitude and depend on light

ing conditions (the type of lighting and indoor versus

outdoor). Different types of light (sunlight, incandescent,

ﬂuorescent) also have different color spectra, and will

produce different output power levels depending on which

type of photovoltaic cell is being used (monocrystalline,

polycrystalline or thin-ﬁlm). Therefore, the photovoltaic

cell must be chosen for the type and amount of light avail

able. Note that the short-circuit output current from the

cell must be at least a few milliamps in order to power

the LTC3108 converter

Non-Boost Applications

The LTC3108 can also be used as an energy harvester

and power manager for input sources that do not require

boosting. In these applications the step-up transformer

can be eliminated.

Any source whose peak voltage exceeds 2.5V AC or 5V

DC can be connected to the C1 input through a current-

limiting resistor where it will be rectiﬁed/peak detected. In

these applications the C2 and SW pins are not used and

can be grounded or left open.

Examples of such input sources would be piezoelectric

transducers, vibration energy harvesters, low current

generators, a stack of low current solar cells or a 60Hz

AC input.

A series resistance of at least 100Ω/V should be used

to limit the maximum current into the VAUX shunt

regulator.

COMPONENT SELECTION

Step-Up Transformer

The step-up transformer turns ratio will determine how

low the input voltage can be for the converter to start.

Using a 1:100 ratio can yield start-up voltages as low as

20mV. Other factors that affect performance are the DC

resistance of the transformer windings and the inductance

of the windings. Higher DC resistance will result in lower

efﬁciency. The secondary winding inductance will deter

mine the resonant frequency of the oscillator, according

to the following formula.

Frequency

2• •L(sec)•C

Where L is the inductance of the transformer secondary

winding and C is the load capacitance on the secondary

winding. This is comprised of the input capacitance at pin

C2, typically 30pF, in parallel with the transformer secondary

winding’s shunt capacitance. The recommended resonant

frequency is in the range of 10kHz to 100kHz. See Table 5

for some recommended transformers.

Table 5. Recommended Transformers

VENDOR PART NUMBER

Coilcraft

www.coilcraft.com

LPR6235-752SML (1:100 Ratio)

LPR6235-253PML (1:20 Ratio)

LPR6235-123QML (1:50 Ratio)

Würth

www.we-online

74488540070 (1:100 Ratio)

74488540120 (1:50 Ratio)

74488540250 (1:20 Ratio)

applicaTions inForMaTion

LTC3108

3108fc

For more information www.linear.com/LTC3108

C1 Capacitor

The charge pump capacitor that is connected from the

transformer’s secondary winding to the C1 pin has an ef

fect on converter input resistance and maximum output

current capability. Generally, a minimum value of 1nF is

recommended when operating from very low input volt

ages using a transformer with a ratio of 1:100. Too large

a capacitor value can compromise performance when

operating at low input voltage or with high resistance

sources. For higher input voltages and lower turns ratios,

the value of the C1 capacitor can be increased for higher

output current capability. Refer to the Typical Applications

schematic examples for the recommended value for a

given turns ratio.

Squegging

Certain types of oscillators, including transformer-coupled

oscillators such as the resonant oscillator of the LTC3108,

can exhibit a phenomenon called squegging. This term

refers to a condition that can occur which blocks or stops

the oscillation for a period of time much longer than the

period of oscillation, resulting in bursts of oscillation. An

example of this is the blocking oscillator, which is designed

to squegg to produce bursts of oscillation. Squegging

is also encountered in RF oscillators and regenerative

receivers.

In the case of the LTC3108, squegging can occur when a

charge builds up on the C2 gate coupling capacitor, such

that the DC bias point shifts and oscillation is extinguished

for a certain period of time, until the charge on the capacitor

bleeds off, allowing oscillation to resume. It is difﬁcult to

predict when and if squegging will occur in a given ap

plication. While squegging is not harmful, it reduces the

average output current capability of the LTC3108.

Squegging can easily be avoided by the addition of a

bleeder resistor in parallel with the coupling capacitor on

the C2 pin. Resistor values in the range of 100k to 1MΩ

are sufﬁcient to eliminate squegging without having any

negative impact on performance. For the 330pF capacitor

used for C2 in most applications, a 499k bleeder resistor

is recommended. See the Typical Applications schematics

for an example.

Using External Charge Pump Rectiﬁers

The synchronous charge pump rectiﬁers in the LTC3108

(connected to the C1 pin) are optimized for operation from

very low input voltage sources, using typical transformer

step-up ratios between 1:100 and 1:50, and typical C1

charge pump capacitor values less than 10nF.

Operation from higher input voltage sources (typically

250mV or greater, under load), allows the use of lower

transformer step-up ratios (such as 1:20 and 1:10) and

larger C1 capacitor values to provide higher output cur

rent capability from the LTC3108. However, due to the

resulting increase in rectiﬁer currents and resonant oscil

lator frequency in these applications, the use of external

charge pump rectiﬁers is recommended for optimal

performance.

In applications where the step-up ratio is 1:20 or less, and

the C1 capacitor is 10nF or greater, the C1 pin should be

grounded and two external rectiﬁers (such as 1N4148 or

1N914 diodes) should be used. These are available as

dual diodes in a single package. Avoid the use of Schottky

rectiﬁers, as their lower forward voltage drop increases

the minimum start-up voltage. See the Typical Applications

schematics for an example.

OUT

and VSTORE Capacitor

For pulsed load applications, the V

OUT

capacitor should

be sized to provide the necessary current when the load

is pulsed on. The capacitor value required will be dictated

by the load current, the duration of the load pulse, and

the amount of voltage droop the circuit can tolerate. The

capacitor must be rated for whatever voltage has been

selected for V

OUT

by VS1 and VS2.

≥C(µF)

I(mA)•t(ms)

V(V)

OUT

LOAD PULSE

OUT

Note that there must be enough energy available from

the input voltage source for V

OUT

to recharge the capacitor

during the interval between load pulses (to be discussed

in the next example). Reducing the duty cycle of the load

pulse will allow operation with less input energy.

applicaTions inForMaTion

P1-P3 P4-P6 P7-P9 P10-P12 P13-P15 P16-P18 P19-P21 P22-P22

LTC3108EDE#PBF

Mfr. #:

Buy LTC3108EDE#PBF

Manufacturer:

Analog Devices / Linear Technology

Description:

Switching Voltage Regulators Ultralow Voltage Step-Up Converter and Power Manager

Lifecycle:

New from this manufacturer.

Delivery:

DHL FedEx Ups TNT EMS

Payment:

T/T Paypal Visa MoneyGram Western Union

LTC3108EDE#PBF

LTC3108EDE#PBF

Products related to this Datasheet