Sipex Corporation SPX1585AT, SPX1585AT-1.5, SPX1585AT-2.5, SPX1585AT-3.3, SPX1585AT-5.0 Datasheet

SPX1585

	5A Low Dropout Voltage Regulator
	Adjustable & Fixed Output,
	Fast Response
FEATURES	APPLICATIONS
• Adjustable Output Down To 1.2V	• Powering VGA & Sound Card
• Fixed Output Voltages 1.5V, 2.5V, 3.3V & 5.0V	• Power PC Supplies
• Output Current Of 5A	• SMPS Post-Regulator
• Low Dropout Voltage 1.1V Typ @ 5A.	• High Efficiency “Green” Computer Systems
• Extremely Tight Load And Line Regulation	• High Efficiency Linear Power Supplies
• Current & Thermal Limiting	• Portable Instrumentation
• Standard 3-Terminal Low Cost TO-220 & TO-263	• Constant Current Regulators
• Similar To Industry Standard LT1085/LT1585	• Adjustable Power Supplies
	• Battery charger

PRODUCT DESCRIPTION

The SPX1585 are low power 5A adjustable and fixed voltage regulators that are very easy to use. It requires only 2 external resistors to set the output voltage for adjustable version. The SPX1585 are designed for low voltage applications that offer lower dropout voltage and faster transient response. This device is an excellent choice for use in powering low voltage microprocessor that require a lower dropout, faster transient response to regulate from +2.5V to 3.8V supplies and as a post regulator for switching supplies applications. The SPX1585 features low dropout of a maximum 1.2 volts.

The SPX1585 offers full protection against over-current faults, reversed input polarity, reversed load insertion, and positive and negative transient voltage. On-Chip trimming adjusts the reference voltage to 1%. The IQ of this device flows into the load, which increases efficiency.

The SPX1585 are offered in a 3-pin TO-220 and TO-263 package compatible with other 3 terminal regulators. For a 8A low dropout regulator refer to the SPX1585 data sheet.

PIN CONNECTIONS

TO-263-3 (T)

3

SPX1585 2

1

Top View

VIN

VOUT

ADJ/GND

TO-220-3 (U)
3	VIN
SPX1585 2	VOUT
1	ADJ/GND
Front View

Rev. 10/23/00

							SPX1585
ABSOLUTE MAXIMUM RATINGS
Lead Temp. (Soldering, 10 Seconds) ..............................		300°C	Input Voltage........................................................						10V
Storage Temperature Range ............................		-65° to +150°C	Input to Output Voltage Differential				....................		10V
Operating Junction Temperature Range
SPX1585 Control Section..........................		-45°C +125°C
SPX1585 Power Transistor.........................		-45°C +150°C
ELECTRICAL CHARACTERISTICS (NOTE 1) at IOUT = 10mA, TA=25°C, unless otherwise specified.
PARAMETER		CONDITIONS	Typ	SPX1585A		SPX1585			UNITS
				Min	Max	Min		Max
1.5V Version
Output Voltage (Note 2)	SPX1585-1.5V, 0 < IOUT < 5A, 3.3V<VIN<10V		1.5	1.485	1.515	1.47		1.53	V
				1.47	1.53	1.455		1.545
2.5V Version
Output Voltage (Note 2)	SPX1585-2.5V, 0 < IOUT < 5A, 4.0V<VIN<10V		2.5	2.475	2.525	2.45		2.55	V
				2.45	2.55	2.425		2.575
3.3V Version
Output Voltage (Note 2)	SPX1585-3.3V, 0 < IOUT< 5A, 4.8V<VIN<10V		3.3	3.267	3.333	3.234		3.366	V
				3.234	3.366	3.069		3.399
5.0V Version
Output Voltage (Note 2)	SPX1585-5.0V, 0 ≤ IOUT ≤ 5A, 6.5V≤VIN≤12V		5	4.950	5.050	4.9		5.1	V
				4.900	5.100	4.65		5.15
All Voltage Options
Reference Voltage (Vref)	VIN≤ 7V, P≤ PMAX		1.250	1.225	1.270	1.225		1.270	V
	1.5V≤ (VIN -VOUT)≤5.75V, 10mA≤IOUT≤5A
Min. Load Current (Note 3)	1.5V≤ (VIN –VOUT)≤5.75V		5		10			10	V
Line Regulation (∆Vref(Vin))	2.75V≤VIN ≤7V, Iout=10mA, TJ=25ºC		0.005		0.2			0.2	%
	(Note 3)
	VIN ≤7V, IOUT=0mA, TJ=25ºC (Note 2)		0.005		0.2			0.2
Load Regulation(∆Vref(Iout))	10mA≤IOUT ≤5A, (VIN-VOUT)=3V, TJ=25ºC (Note 3)		0.05		0.3			0.3	%
	0≤IOUT ≤5A, VIN=7V, TJ=25ºC (Note 2)		0.05		0.3			0.3
Dropout Voltage	∆VREF=1%	IOUT = 5A (Note 3)	1.1		1.2			1.2
		IOUT < 5A (Note 2)
Current Limit	VIN=7V		6	5.2		5.2			A
Iout(MAX)
	1.4V ≤ (VIN - VOUT) (Note3)
Long Term Stability	TA=125ºC, 1000 Hrs.		0.3		1			1	%
			(Note 2)
Thermal Regulation	TA=25ºC, 20 ms pulse		0.01		0.020			0.020	%/W
(∆Vout(Pwr))
Temperature Stability			0.25						%
(∆Vout(T))
Output Noise, RMS	10Hz to 10kHz	TA=25ºC	0.003						% Vo
Thermal Resistance	TO-220	Junction to Tab			3.0			3.0	ºC/W
		Junction to Ambient
					60			60
	DD Package	Junction to Tab			3.0			3.0
		Junction to Ambient
					60			60

The Bold specifications apply to the full operating temperature range.

Note 1: Changes in output voltage due to heating effects are covered under the specification for thermal regulation.

Note 2: Fixed Version Only

Note 3: Adjustable Version Only

Rev. 10/23/00

SPX1585

APPLICATION HINTS

The SPX1585 incorporates protection against over-current faults, reversed load insertion, over temperature operation, and positive and negative transient voltage. However, the use of an output capacitor is required in order to insure the stability and the performances.

Stability

The output capacitor is part of the regulator’s frequency compensation system. Either a 22µF aluminum electrolytic capacitor or a 10µF solid tantalum capacitor between the output terminal and ground guarantees stable operation for all operating conditions.

However, in order to minimize overshoot and undershoot, and therefore optimize the design, please refer to the section ‘Ripple Rejection’.

Ripple Rejection

Ripple rejection can be improved by adding a capacitor between the ADJ pin and ground. When ADJ pin bypassing is used, the value of the output capacitor required increases to its maximum (220µF for an aluminum electrolytic capacitor, or 47µF for a solid tantalum capacitor). If the ADJ pin is not bypass, the value of the output capacitor can be lowered to 10µF for an electrolytic aluminum capacitor or 4.7µF for a solid tantalum capacitor.

However the value of the ADJ-bypass capacitor should be chosen with respect to the following equation:

C = 1 / ( 6.28 * FR * R1 )

Where C	= value of the capacitor in Farads (select an
equal or larger standard value),
FR	= ripple frequency in Hz,
R1	= value of resistor R1 in Ohms.

If an ADJ-bypass capacitor is use, the amplitude of the output ripple will be independent of the output voltage. If an ADJbypass capacitor is not used, the output ripple will be proportional to the ratio of the output voltage to the reference voltage:

M = VOUT / VREF

Where M = multiplier for the ripple seen when the ADJ pin is optimally bypassed.

VREF = Reference Voltage

Reducing parasitic resistance and inductance

One solution to minimize parasitic resistance and inductance is to connect in parallel capacitors. This arrangement will improve the transient response of the power supply if your system requires rapidly changing current load condition.

Thermal Consideration

Although the SPX1585 offers some limiting circuitry for overload conditions, it is necessary not to exceed the maximum junction temperature, and therefore to be careful about thermal resistance. The heat flow will follow the lowest resistance path, which is the Junction-to-case thermal resistance. In order to insure the best thermal flow of the component, a proper mounting is required. Note that the case of the device is electrically connected to the output. In case the case has to be electrically isolated, a thermally conductive spacer can be used. However do not forget to consider its contribution to thermal resistance.

Assuming:

VIN = 10V, VOUT = 5V, IOUT = 1.5A, TA = 50°C/W,

θHeatsink Case= 6°C/W, θHeatsink Case = 0.5°C/W, θ JC = 3°C/W

Power dissipation under this condition

PD = (VIN – VOUT) * IOUT = 7.5W

Junction Temperature

TJ = TA + PD * (θCase – HS + θ HS θ JC)

For the Control Section

TJ = 50 + 7.5*(0.5 + 6=3) = 121.25°C

121.25°C < TJ (max) for the Control & Power Sections.

In both case reliable operation is insured by adequate junction temperature.

Rev. 10/23/00