features: series hermetic surface mount package extremely low dropout voltage: 350mv @ 3 amps available in 1.5v, 1.7v, 1.8v, 1.9v, 2.5v, 3.3v, 5.0v and 12.0v on board thermal shut down reverse battery and load dump protection low ground current: 42ma typical at full load 1% maximum guaranteed accuracy output current to 3 amps alternate output voltages available description: the msk5230 series voltage regulators are available in +1.5v, +1.7v, +1.8v, +1.9v, +2.5v, +3.3v, +5.0v, and +12.0v output confgurations. all boast ultra low dropout specifcations due to the utilization of a super pnp output pass transistor with monolithic technology. dropout voltages of 350mv at 3 amps are typical in this confguration, which drives effciency up and power dissipation down. accuracy is guaranteed with a 1% maximum output voltage tolerance. the msk5230 series is packaged in a space effcient 3 pin power surface mount ceramic package. equivalent schematic 5230 typical applications pin-out information high effciency, high current linear regulators constant voltage/current regulators system power supplies switching power supply post regulators battery powered equipment v in v out ground 1 2 3 1 mil-prf-38534 and 38535 certified facility high current, low dropout surface mount voltage regulators lid=isolated 8548-39 rev. j 4/15
output current limit 2 output noise 2 thermal resistance 2 thermal shutdown 2 input voltage (100ms 1%d.c.) input voltage enable voltage output current -20v to +60v 26v -0.3v to 26v 3.0a storage temperature range -65c to +150c lead temperature (10 seconds soldering) 300c operating temperature msk5230 series -40c to +85c msk5230h series -55c to +125c esd rating class 2 v inp v in v en i out t st t ld t j absolute maximum ratings 2 ? v out = -1%; i out = 100 ma ? v out = -1%; i out = 3a (v out +1v) v in 26v i out = 10 ma v out = 0v; v in = v out +1v v in = v out +1v; i out = 1.5a v in = v out +1v; i out = 3a c l = 20f; 10 h z f 100 kh z junction to case @ 125c t j ground current 2 8 1 2, 3 1 1 1 2, 3 1 2, 3 - - - - - - parameter electrical specifications - - - - - - - - - - - - - - 0.5 1.0 80 350 0.2 0.3 0.05 0.5 4.5 20 42 400 3.3 130 1.0 2.0 200 600 1.0 2.0 0.5 1.0 5.0 45 - - 3.7 - % % mv mv % % % % a ma ma v c/w c - - - - - - - - - - - - - - 0.5 - 80 350 0.2 0.3 0.05 0.5 4.5 20 42 400 3.3 130 1.0 - 225 625 1.2 - 0.6 - 5.0 45 - - 3.9 - group a subgroup msk5230h series min. typ. max. msk5230 series min. typ. max. units test conditions 1 3 output voltage tolerance dropout voltage 2 load regulation 8 line regulation i out = 10ma; v in = v out +1v +1.5v +1.7v +1.8v +1.9v +2.5v +3.3v +5.0v +12.0v age 7 number 1 2 3 4 5 6 7 8 9 10 notes: output decoupled to ground using 47f minimum capacitor unless otherwise specifed. this parameter is guaranteed by design but need not be tested. typical parameters are representative of actual device performance but are for reference only. all output parameters are tested using a low duty cycle pulse to maintain tj = tc. industrial grade devices shall be tested to subgroup 1 unless otherwise specifed. military grade devices ('h' suffx) shall be 100% tested to subgroups 1,2,3. subgroup 1 subgroup 2 subgroup 3 please consult the factory if alternate output voltages are required. due to current limit, maximum output current may not be available at all values of v in -v out and temperatures. see typical performance curves for clarifcation. the output current limit function provides protection from transient overloads but it may exceed the maximum continuous rating. continuous operation in current limit may damage the device. continuous operation at or above absolute maximum ratings may adversely effect the device performance and/or life cycle. t c = +25c t j = +125c t a = -55c msk5230-1.5 msk5230-1.7 msk5230-1.8 msk5230-1.9 msk5230-2.5 msk5230-3.3 msk5230-5.0 msk5230-12 10 ma i out 2.5a 10 9 8548-39 rev. j 4/15
first, the power dissipation must be calculated as follows: power dissipation = (vin - vout) x iout next, the user must select a maximum junction temperature. the absolute maximum allowable junction temperature is 125c. the equation may now be rearranged to solve for the required heat sink to ambient thermal resistance (r sa). example: an msk5230-3.3 is confgured for vin=+5v and vout=+3.3v. iout is a continuous 1a dc level. the ambient temperature is +25c. the maximum desired junction temperature is 125c. r jc = 3.3c/w and r cs = 0.5c/w typically. power dissipation = (5v - 3.3v) x (1a) = 1.7 watts solve for r sa: r sa = 125c - 25c - 3.3c/w - 0.5c/w in this example, a heat sink with a thermal resistance of no more than 55c/w must be used to maintain a junction temperature of no more than 125c. ] application notes regulator protection: the msk5230 series is fully protected against reversed input polarity, overcurrent faults, overtemperature conditions (pd) and transient voltage spikes of up to 60v. if the regulator is used in dual supply systems where the load is returned to a negative supply, the output voltage must be diode clamped to ground. load connections: in voltage regulator applications where very large load currents are present, the load connection is very important. the path connecting the output of the regulator to the load must be extremely low impedance to avoid affecting the load regulation specifcations. any impedance in this path will form a voltage divider with the load. minimizing power dissipation: many applications can not take full advantage of the ex - tremely low dropout specifcations of the regulator due to large input to output voltage differences. the simple circuit below illustrates a method to reduce the input voltage at the regulator to just over the dropout specifcation to keep the internal power dissipation minimized: for a given continuous maximum load of 1 amp, r1 can be selected to drop the voltage seen at the regulator to 4v. this allows for the output tolerance and dropout specifcations. input voltage variations (5v) also should be included in the calculations. the resistor should be sized according to the power levels required for the application. output capacitor: the output voltage ripple of the msk5230 series voltage regulators can be minimized by placing a flter capacitor from the output to ground. the optimum value for this capacitor may vary from one application to the next, but a minimum of 20f is recommended for optimum performance. transient load response can also be improved by placing a capacitor directly across the load. the capacitor should not be an ultra-low esr type. tantalum capacitors are best for fast load transients but aluminum electrolytics will work fne in most applications. 3 1.7w package connections: the msk5230 series are highly thermally conductive de - vices and the thermal path from the package heat sink to the internal junctions is very short. standard surface mount soldering techniques should be used when mounting the device. some applications may require additional heat sinking of the device. heat sink selection: to select a heat sink for the msk5230, the following formula for convective heat fow may be used. governing equation: tj = pd x (r jc + r cs + r sa) + ta where: tj = junction temperature pd = total power dissipation r jc = junction to case thermal resistance r cs = case to heat sink thermal resistance r sa = heat sink to ambient thermal resistance ta = ambient temperature [ 8548-39 rev. j 4/15
typical performance curves 4 8548-39 rev. j 4/15
msk5230-3.3 h 5 mechanical specifications ordering information screening blank= industrial; h= mil-prf-38534 class h output voltage 1.5=+1.5v; 1.7=+1.7v; 1.8=+1.8v; 1.9= +1.9v; 2.5=+2.5v; 3.3=+3.3v; 5.0=+5.0v; 12=+12.0v general part number the above example is a +3.3v, military regulator. 8548-39 rev. j 4/15 weight=2.3 grams typical all dimensions are specified in inches
msk www.anaren.com/msk the information contained herein is believed to be accurate at the time of printing. msk reserves the right to make changes to its products or specifcations without notice, however , and assumes no liability for the use of its products. please visit our website for the most recent revision of this datasheet. 6 8548-39 rev. j 4/15 revision history
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