7*%&0108&301&3"5*0/"-".1-*'*&3 PA09 * PA09A M I C R O T E C H N O L O G Y )551888"1&9.*$305&$)$0. "1&9 FEATURES * * * * * * * POWER MOS TECHNOLOGY -- 2A peak rating HIGH GAIN BANDWIDTH PRODUCT -- 150MHz VERY FAST SLEW RATE -- 200V/s PROTECTED OUTPUT STAGE -- Thermal shutoff EXCELLENT LINEARITY -- Class A/B output WIDE SUPPLY RANGE -- 12V to 40V LOW BIAS CURRENT, LOW NOISE -- FET input 8-pin TO-3 PACKAGE STYLE CE APPLICATIONS * * * * * DEFLECTION AMPLIFIER (Figure 1) VIDEO DISTRIBUTION AND AND AMPLIFICATION HIGH SPEED DEFLECTION CIRCUITS POWER TRANSDUCERS TO 2MHz COAXIAL LINE DRIVERS POWER LED OR LASER DIODE EXCITATION DESCRIPTION The PA09 is a high voltage, high output current operational amplifier optimized to drive a variety of loads from DC through the video frequency range. Excellent input accuracy is achieved with a dual monolithic FET input transistor which is cascoded by two high voltage transistors to provide outstanding common mode characteristics. All internal current and voltage levels are referenced to a zener diode biased on by a current source. As a result, the PA09 exhibits superior DC and AC stability over a wide supply and temperature range. High speed and freedom from second breakdown is assured by a complementary Power MOS output stage. For optimum linearity, especially at low levels, the Power MOS transistors are biased in the class A/B mode. Thermal shutoff provides full protection against overheating and limits the heatsink requirements to dissipate the internal power losses under normal operating conditions. A built-in current limit protects the amplifier against overloading. Transient inductive load kickback protection is provided by two internal clamping diodes. External phase compensation allows the user maximum flexibility in obtaining the optimum slew rate and gain bandwidth product at all gain settings. For continuous operation under load, a heatsink of proper rating is recommended. This hybrid integrated circuit utilizes thick film (cermet) resistors, ceramic capacitors and silicon semiconductor chips to maximize reliability, minimize size and give top performance. Ultrasonically bonded aluminum wires provide reliable interconnections at all operating temperatures. The CE, 8-pin TO-3 package is hermeti7 EJ "T $$Q' cally sealed and elecEU trically isolated. The J7J34 use of com-pressible 7* thermal washers and/ 1" $' -: or improper mounting Q' ) torque will void the 3% product warranty. m7 3' , Please see "General Operating Consider 3 4 ations". '*(63&1""4%&'-&$5*0/".1-*'*&3 The deflection amplifier circuit of Figure 1 achieves arbitrary beam positioning for a fast heads-up display. Maximum transition times are 4s while delivering 2A pk currents to the 13mH coil. The key to this circuit is the sense resistor (RS) which converts yoke current to voltage for op amp feedback. This negative feedback forces the coil current to stay exactly proportional to the control voltage. The network consisting of RD, RF and CF serves to shift from a current feedback via RS to a direct voltage feedback at high frequencies. This removes the extra phase shift caused by the inductor thus preventing oscillation. See Application Note 5 for details of this and other precision magnetic deflection circuits. EQUIVALENT SCHEMATIC % $ 2 2 2 2 2 2 2 2 2 2" 2 2 2# $ 2 2 2 2 % 2 2 % 2 EXTERNAL CONNECTIONS 74 35 */ 34 #" 065 5017*&8 m*/ m74 $$ 3$ $$ 34 ] 74] ]m74] 35 /05&*OQVUPGGTFUWPMUBHFUSJNPQUJPOBM35,."9 APEX MICROTECHNOLOGY CORPORATION * TELEPHONE (520) 690-8600 * FAX (520) 888-3329 * ORDERS (520) 690-8601 * EMAIL prodlit@apexmicrotech.com PA09 * PA09A ABSOLUTE MAXIMUM RATINGS ABSOLUTE MAXIMUM RATINGS SPECIFICATIONS Supply voltage, +VS to -VS Output current, within SOA Power dissipation, internal1 Input voltage, differential Input voltage, common mode Temperature, pin solder - 10s Temperature, junction1 Temperature range, storage Operating temperature range, case SPECIFICATIONS PARAMETER TEST CONDITIONS 2 MIN PA09 TYP MAX 80V 5A 78W 40V VS 300C 150C -65 to +150C -55 to +125C MIN INPUT Offset voltage, initial .5 3 Offset voltage, vs. temperature Full temperature range 10 30 Offset voltage, vs. supply 10 Bias current, initial 5 100 Bias current, vs. supply .01 Offset current, initial 2.5 50 1011 Input impedance, dc Input capacitance 6 Common mode voltage range3 Full temperature range VS-10 VS-8 * Common mode rejection, dc Full temperature range, VCM = 20V 104 GAIN Open loop gain at 15Hz Gain bandwidth product at 1MHz Power bandwidth Power bandwidth RL = 1k 80 CC = 5pF RL = 15, CC = 5pF RL = 15, CC = 100pF 98 150 750 150 PA09A TYP MAX UNITS .25 .5 mV 5 10 V/C * V/V 3 20 pA * pA/V 1.5 10 pA * * pF *V * dB * * * * dB MHz KHz KHz OUTPUT Voltage swing3 Full temperature range, IO = 2A VS -8 VS -7 * Current, peak 4.5 Settling time to 1% 4V step, CC = 100pF .75 Settling time to .1% 4V step, CC = 100pF 1.3 Slew rate CC = 5pF 220 Slew rate CC = 100pF 25 RESISTANCE 7.5 *V * A * s * s *V/s *V/s * POWER SUPPLY Voltage Full temperature range 12 Current, quiescent 35 70 * * THERMAL Resistance, AC junction to case4 Resistance, DC junction to case Resistance, junction to air Temperature range, case 1.2 1.3 1.6 1.8 30 25 + 85 * Full temperature range, F > 60Hz Full temperature range, F < 60Hz Full temperature range Meets full range specifications -25 40 * 85 *V * mA * * * * * * * C/W C/W C/W C NOTES: * The specification of PA09A is identical to the specification for PA09 in applicable column to the left. 1.Long term operation at the maximum junction temperature will result in reduced product life. Derate power dissipation to achieve high MTTF. 2. Unless otherwise noted: TC = 25C, supply voltage = 35V. 3. +VS and -VS denote the positive and negative supply rail respectively. Total VS is measured from +VS to -VS. 4. Rating applies if the output current alternates between both output transistors at a rate faster than 60Hz. CAUTION The internal substrate contains beryllia (BeO). Do not break the seal. If accidentally broken, do not crush, machine, or subject to temperatures in excess of 850C to avoid generating toxic fumes. APEX MICROTECHNOLOGY CORPORATION * 5980 NORTH SHANNON ROAD * TUCSON, ARIZONA 85741 * USA * APPLICATIONS HOTLINE: 1 (800) 546-2739 PA09 * PA09A TYPICAL PERFORMANCE GRAPHS $"4&5&.1&3"563& 5$ $ 4."--4*(/"-3&410/4& Q' Q' Q' Q' 06516570-5"(&48*/( 065165$633&/5 *0 " 1)"4&3&410/4& -08 ("*/ 01&/-0011)"4& )*() $0..0/.0%&3&+&$5*0/ , , , . . . '3&26&/$: ' )[ Q' Q' "-05)&34 Q' Q' Q' , $0.1&/4"5*0/$"1"$*503 $$ Q' 108&34611-:3&+&$5*0/ 143 E# ("*/"/%4-&83"5& 7T $0..0/.0%&3&+&$5*0/ $.3 E# 7T 505"-4611-:70-5"(& 74 7 , , , . . . '3&26&/$: ' )[ , , , . . . '3&26&/$: ' )[ Q' Q' Q' Q' Q' , , '3&26&/$: ' ,)[ . */165/0*4& 108&34611-:3&+&$5*0/ 108&33&410/4& Q' , , , . . . '3&26&/$: ' )[ 4-&83"5&WT$0.1 70-5"(&%301'30.4611-: 7 01&/-001("*/ " E# Q' m m +6/$5*0/5&.1&3"563& 5+ $ 26*&4$&/5$633&/5 06516570-5"(& 70 711 /03."-*;&%26*&4$&/5$633&/5 *2 9 */165/0*4&70-5"(& 7/ O7)[ $633&/5-*.*5 *-*. " */5&3/"-108&3%*44*1"5*0/ 1 8 $633&/5-*.*5 $0..0/.0%&70-5"(& 7$. 711 108&3%&3"5*/( , , , '3&26&/$: ' )[ . $0..0/.0%&70-5"(& ] 74] ]m74]7 $$Q' , , . . . . '3&26&/$: ' )[ APEX MICROTECHNOLOGY CORPORATION * TELEPHONE (520) 690-8600 * FAX (520) 888-3329 * ORDERS (520) 690-8601 * EMAIL prodlit@apexmicrotech.com OPERATING CONSIDERATIONS PA09 * PA09A GENERAL Please read Application Note 1 "General Operating Considerations" which covers stability, supplies, heat sinking, mounting, current limit, SOA interpretation, and specification interpretation. Visit www.apexmicrotech.com for design tools that help automate tasks such as calculations for stability, internal power dissipation, current limit; heat sink selection; Apex's complete Application Notes library; Technical Seminar Workbook; and Evaluation Kits. SUPPLY VOLTAGE The specified voltage (VS) applies for a dual () supply having equal voltages. A nonsymmetrical (ie. +70/-10V) or a single supply (ie. 80V) may be used as long as the total voltage between the +VS and -VS rails does not exceed the sum of the voltages of the specified dual supply. SAFE OPERATING AREA (SOA) The MOSFET output stage of this power operational amplifier has two distinct limitations: 1. The current handling capability of the MOSFET geometry and the wire bonds. 2. The junction temperature of the output MOSFETs. 065165$633&/5'30. 7403m74 " 40" 5$$ U U TU FB EZ N T N T T UB UF */5&3/"-70-5"(&%3014611-:5006516574m70 7 SAFE OPERATING AREA CURVES The SOA curves combine the effect of these limits and allow for internal thermal delays. For a given application, the direction and magnitude of the output current should be calculated or measured and checked against the SOA curves. This is simple for resistive loads but more complex for reactive and EMF generating loads. The following guidelines may save extensive analytical efforts: 1. Capacitive and inductive loads up to the following maximums are safe: VS CAPACITIVE LOAD INDUCTIVE LOAD 40V .1F 11mH 30V 500F 24mH 20V 2500F 75mH 15V 100mH 2. Short circuits to ground are safe with dual supplies up to 20V. 3. The output stage is protected against transient flyback. However, for protection against sustained, high energy flyback, external fast-recovery diodes should be used. BYPASSING OF SUPPLIES Each supply rail must be bypassed to common with a tantalum capacitor of at least 47F in parallel with a .47F ceramic capacitor directly connected from the power supply pins to the ground plane. OUTPUT LEADS Keep the output leads as short as possible. In the video frequency range, even a few inches of wire have significant inductance, raising the interconnection impedance and limiting the output current slew rate. Furthermore, the skin effect increases the resistance of heavy wires at high frequencies. Multistrand Litz Wire is recommended to carry large video currents with low losses. GROUNDING Single point grounding of the input resistors and the input signal to a common ground plane will prevent undesired current feedback, which can cause large errors and/or instabilities. "Single point" is a key phrase here; a ground plane should be used as shielding rather than a current path. Leaving the case of the PA09 floating will cause oscillations in some applications. COMPENSATION The PA09 is extremely flexible in terms of choice of compensation capacitor for any given gain. The most common ranges are shown in the COMPENSATION typical performance graph. Swinging closer to the supply rails, heavier loads, faster input signal rise and fall times and higher supply voltages all tend to demand larger values of compensation capacitor. This capacitor must be rated at least as high as the total voltage applied to the amplifier. In making specific value choices, use the square wave stability test presented in APPLICATION NOTE 19, Figures 40 and 41. In addition to small signal testing, if the application includes step functions in the input signal, use this circuit to measure large signal response. By increasing square wave amplitude to the maximum of the application, this test may show significant distortion of the output waveform following the square wave transitions. In this case the faster input stages of the PA09 are out-running the output stage and overload recovery time creates the distortion. This speed relationship is also why slew rate does not increase for compensation values below about 27pF. SUPPLY CURRENT When swinging large signals, the output stage of the PA09 demands extra supply current. The following graphs illustrate this current for several conditions for both sine and square wave signals. Current is exclusive of any load current and will APEX MICROTECHNOLOGY CORPORATION * 5980 NORTH SHANNON ROAD * TUCSON, ARIZONA 85741 * USA * APPLICATIONS HOTLINE: 1 (800) 546-2739 PA09 * PA09A OPERATING CONSIDERATIONS affect both supply rating and thermal ratings. When calculating internal power dissipation, multiply this current times total supply voltage. 26*&4$&/5WT4*/&%3*7& STABILITY 7 0 0 7 7 4 7 4 7 4 /03."-*;&%*2 9 7 0 '3&26&/$: ' ,)[ 26*&4$&/5WT426"3&%3*7& /03."-*;&%*2 9 7074 7074 7074 , '3&26&/$: ' ,)[ Due to its large bandwidth the PA09 is more likely to oscillate than lower bandwidth Power Operational Amplifiers. To prevent oscillations a reasonable phase margin must be maintained by: 1. Pay very careful attention to supply bypassing and circuit grounding. This is very important when step functions are driven and the PA09 shares supplies with more active devices. 2. Keeping the external sumpoint stray capacitance to ground at a minimum and the sumpoint load resistance (input and feedback resistors in parallel) below 500. Larger sumpoint load resistances can be used with increased phase compensation and/or bypassing of the feedback resistor. 3. Connect the case to a local AC ground potential. CURRENT LIMIT Internal current limiting is provided in the PA09. Note the current limit curve given under typical performance graphs is based on junction temperature. If the amplifier is operated at cold junction temperatures, current limit could be as high as 8 amps. This is above the maximum allowed current on the SOA curve of 5 amps. Systems using this part must be designed to keep the maximum output current to less than 5 amps under all conditions. The internal current limit only provides this protection for junction temperatures of 80C and above. , oscillate in and out of shutdown. This will result in high peak power stresses, destroy signal integrity, and reduce the reliability of the device. . Note that swinging closer to the supply rail demands more current. Output voltage is given as peak. Currents are average responding supply readings, but AC monitoring will reveal current pulses corresponding to periods of high slew rate. For example, driving 30V outputs at 500KHz on 40V supplies produces a .8A pulse during negative slew and a 1.2A pulse during positive slew. If the input signal is over driven by several times the output swing capability, pulses up to 4A may be seen. THERMAL SHUTDOWN PROTECTION The thermal protection circuit shuts off the amplifier when the substrate temperature exceeds approximately 150C. This allows heatsink selection to be based on normal operating conditions while protecting the amplifier against excessive junction temperature during temporary fault conditions. Thermal protection is a fairly slow-acting circuit and therefore does not protect the amplifier against transient SOA violations (areas outside of the TC = 25C boundary). It is designed to protect against short-term fault conditions that result in high power dissipation within the amplifier, If the conditions that cause thermal shutdown are not removed, the amplifier will This data sheet has been carefully checked and is believed to be reliable, however, no responsibility is assumed for possible* inaccuracies or omissions. All specifications subject to change without notice. APEX MICROTECHNOLOGY CORPORATION * TELEPHONE (520) 690-8600 * FAX (520) 888-3329 ORDERS (520) 690-8601 * EMAILare prodlit@apexmicrotech.com PA09U REV L OCTOBER 2006 (c) 2006 Apex Microtechnology Corp.