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MAX8863T/S/R,� MAX8864T/S/R�
�
Low-Dropout,� 120mA� Linear� Regulators�
�
Operating� Region� and� Power� Dissipation�
�
Maximum� power� dissipation� of� the� MAX8863/MAX8864�
�
depends� on� the� thermal� resistance� of� the� case� and� cir-�
�
cuit� board,� the� temperature� difference� between� the� die�
�
junction� and� ambient� air,� and� the� rate� of� air� flow.� The�
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power� dissipation� across� the� device� is� P� =� I� OUT� (V� IN� -�
�
V� OUT� ).� The� resulting� maximum� power� dissipation� is:�
�
P� MAX� =� (T� J� -� T� A� )� /� θ� JA�
�
where� (T� J� -� T� A� )� is� the� temperature� difference� between�
�
the� MAX8863/MAX8864� die� junction� and� the� surround-�
�
ing� air,� and� θ� JA� is� the� thermal� resistance� of� the� chosen�
�
package� to� the� surrounding� air.�
�
The� GND� pin� of� the� MAX8863/MAX8864� performs� the�
�
dual� function� of� providing� an� electrical� connection� to�
�
ground� and� channeling� heat� away.� Connect� the� GND�
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pin� to� ground� using� a� large� pad� or� ground� plane.�
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Reverse� Battery� Protection�
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The� MAX8863/MAX8864� have� a� unique� protection�
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scheme� that� limits� the� reverse� supply� current� to� less�
�
than� 1mA� when� either� V� IN� or� V� SHDN� falls� below� ground.�
�
The� circuitry� monitors� the� polarity� of� these� two� pins,� dis-�
�
connecting� the� internal� circuitry� and� parasitic� diodes�
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when� the� battery� is� reversed.� This� feature� prevents� the�
�
device� from� overheating� and� damaging� the� battery.�
�
V� IN� >� 5.5V� Minimum� Load� Current�
�
When� operating� the� MAX8863/MAX8864� with� an� input�
�
voltage� above� 5.5V,� a� minimum� load� current� of� 20μA� is�
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required� to� maintain� regulation� in� preset� voltage� mode.�
�
When� setting� the� output� with� external� resistors,� the� min-�
�
imum� current� through� the� external� feedback� resistors�
�
and� load� must� be� 30μA.�
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__________Applications� Information�
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Capacitor� Selection� and�
�
Regulator� Stability�
�
Normally,� use� a� 1μF� capacitor� on� the� input� and� a� 1μF�
�
capacitor� on� the� output� of� the� MAX8863/MAX8864.�
�
Larger� input� capacitor� values� and� lower� ESR� provide�
�
better� supply-noise� rejection� and� transient� response.� A�
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higher-value� input� capacitor� (10μF)� may� be� necessary�
�
8�
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if� large,� fast� transients� are� anticipated� and� the� device� is�
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located� several� inches� from� the� power� source.� Improve�
�
load-transient� response,� stability,� and� power-supply�
�
rejection� by� using� large� output� capacitors.� For� stable�
�
operation� over� the� full� temperature� range,� with� load� cur-�
�
rents� up� to� 120mA,� a� minimum� of� 1μF� is� recommended.�
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Noise�
�
The� MAX8863/MAX8864� exhibit� 350μV� RMS� noise� during�
�
normal� operation.� When� using� the� MAX8863/MAX8864�
�
in� applications� that� include� analog-to-digital� converters�
�
of� greater� than� 12� bits,� consider� the� ADC’s� power-sup-�
�
ply� rejection� specifications� (see� the� Output� Noise� DC� to�
�
1MHz� photo� in� the� Typical� Operating� Characteristics).�
�
Power-Supply� Rejection� and� Operation�
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from� Sources� Other� than� Batteries�
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The� MAX8863/MAX8864� are� designed� to� deliver� low�
�
dropout� voltages� and� low� quiescent� currents� in� battery-�
�
powered� systems.� Power-supply� rejection� is� 62dB� at�
�
low� frequencies� and� rolls� off� above� 300Hz.� As� the� fre-�
�
quency� increases� above� 20kHz,� the� output� capacitor� is�
�
the� major� contributor� to� the� rejection� of� power-supply�
�
noise� (see� the� Power-Supply� Rejection� Ratio� vs.�
�
Ripple� Frequency� graph� in� the� Typical� Operating�
�
Characteristics).�
�
When� operating� from� sources� other� than� batteries,�
�
improve� supply-noise� rejection� and� transient� response�
�
by� increasing� the� values� of� the� input� and� output� capac-�
�
itors,� and� using� passive� filtering� techniques� (see� the�
�
supply� and� load-transient� responses� in� the� Typical�
�
Operating� Characteristics).�
�
Load� Transient� Considerations�
�
The� MAX8863/MAX8864� load-transient� response�
�
graphs� (see� Typical� Operating� Characteristics)� show�
�
two� components� of� the� output� response:� a� DC� shift� of�
�
the� output� voltage� due� to� the� different� load� currents,�
�
and� the� transient� response.� Typical� overshoot� for� step�
�
changes� in� the� load� current� from� 0mA� to� 50mA� is�
�
12mV.� Increasing� the� output� capacitor� ’s� value� and�
�
decreasing� its� ESR� attenuates� transient� spikes.�
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Maxim� Integrated�
�