STM901-30 RF POWER MODULE LINEAR BASE STATION APPLICATIONS .. .. .. LINEAR POWER AMPLIFIER 860 - 900 MHz 26 VOLTS INPUT/OUTPUT 50 OHMS P OU T = +44.7 dBm PEP GAIN = 35 dB MIN. CASE STYLEH141 ORDER CODE STM901-30 BRANDING STM901-30 PIN CONNECTION DESCRIPTION The STM901-30 module is designed for digital cellular radio base station applications in the 860-900 MHz frequency range operating at 26V. The STM901-30 is designed to meet the low distortion, high linearity requirements of modern digital cellular base station equipment. 1. RF Input 5. VD 9. VB2 2. VG1 6. VB1 10. Cap2 3. deleted 4. VG2 7. Cap1 8. VC1 11. VC2 12. RF Output ABSOLUTE MAXIMUM RATINGS (Tcase = 25 °C) Symbol Parameter V, VD , V C1 , VC2 DC Supply Voltage Value Unit 28 Vdc I Q1 Bias Current @ V = 26V, 1st Stage 0.40 Adc I Q2 Bias Current @ V = 26V, 2nd Stage 0.40 Adc I Q3 Bias Current @ V = 26V, 3rd Stage 0.54 Adc I Q4 Bias Current @ V = 26V, 4th Stage 1.62 Adc PI N RF Input Power (P OUT < 44.7 dBm PEP) 14 dBm PEP P OU T RF Output Power (V = 26V) 48 dBm PEP T STG Storage Temperature − 30 to +100 °C T OPE R Operating Temperature − 30 to +100 °C October 31, 1997 1/8 STM901-30 ELECTRICAL SPECIFICATIONS (Tcase = 25°C, V D , V C1 , V C2 = 26V) (I DQ1 = 100mA, IDQ2 = 180mA, I CQ1 = 50mA, I C Q2 =150mA) Symbol Parameter BW Frequency Range GP Power Gain η dt * Value T est Cond itions Un it Min. Typ. Max. 860 — 900 MHz POUT = +44.7 dBm PEP 35 38 — dB Double-Tone Efficiency POUT = +44.7 dBm PEP 27 30 — % Input VSWR POUT = +44.7 dBm PEP — 1.5:1 3:1 IMD* Intermodulation Distortion POUT = +44.7 dBm PEP — −33 −26 dBT** — Load Mismatch V = 26Vdc VSWR = 5:1 POUT = +44.7 dBm PEP No Degradation in Output Power Note: * Two- Tone test; 20 KHz separation ** dBT - i n dB, refer enced to tone level (See Figure 1 below) PEP (Peak Envelope Power) Carrier Level Total Avg. Power of Two Tone AVERAGE Power of Ea ch Tone 3 dB min 3 dB min 26 dB min Max IMD in dBT freq 20 kHz Figure 1 2/8 October 31, 1997 STM901-30 TYPICAL PERFORMANCE POWER GAIN vs OUTPUT POWER & FREQUENCY POWER GAIN vs PEP & FREQUENCY POWER GAIN vs OUTPUT POWER & FREQUENCY POWER GAIN vs PEP & FREQUENCY 42.5 f=860 MHz f=900 MHz POWER GAIN [dB] 41.5 f=925 MHz 40.5 39.5 38.5 f=960 MHz 37.5 36.5 Vs=26.0, Tc=25°C Iq=0.1/0.18/0.1/0.15 A 35 40 45 PEP [dBm] POWER GAIN vs OUTPUT POWER & FREQUENCY October 31, 1997 POWER GAIN vs PEP & FREQUENCY 3/8 STM901-30 TYPICAL PERFORMANCE 3rd ORDER IMD vs PEP 5th ORDER IMD vs PEP 3rd ORDER IMD vs PEP 5th ORDER IMD vs PEP 3rd ORDER IMD vs PEP 5th ORDER IMD vs PEP -20 V s=26.0, Tc=+85°C I q=0.1/0.18/0.05/0.15 A f=960 MHz f=925 M Hz 3rd IMD [dBT] -25 f=860 MHz -30 -35 -40 f=900 MHz 20 25 30 35 40 45 PEP [dBm] 4/8 October 31, 1997 STM901-30 TYPICAL PERFORMANCE CW EFFICIENCY vs OUTPUT POWER & FREQUENCY EFFICIENCY vs FREQUENCY GAIN & RETURN LOSS vs FREQUENCY October 31, 1997 5/8 STM901-30 MODULE DC AND TEST FIXTURE CONFIGURATION C1, C3, C5, C7, C11, C13, C 17 : 100 pF C2, C4, C6, C8, C12, C14, C 18 : .001 µF C19 : .1 µF C20, C22 : 100 µF F1, F2, F3 : FAIR-RITE #2664000101 L1, L2, L3 : 5 Turns of 24 AWG Wi re, Inner Diameter 1.27mm R1, R2, R3, R4 : 20 KOHM 6/8 Setting Bias: (Ex.: IQ1 = .1A, IQ2 = .18A, IQ3 = .050A, IQ4 = .150A) 1. Set all variable resistors clockwise. (No bias current flows through transistors when all variable resistors are set clockwise.) 2. Record stationary current I O. 3. Adjust R1 for (IO + 100)mA. 4. Adjust R2 for (IO + 100 + 180)mA. 5. Adjust R3 for (IO + 100 + 180 + 50)mA. 6. Adjust R4 for (IO + 100 + 180 + 50 + 150)mA. October 31, 1997 STM901-30 APPLICATIONS RECOMMENDATIONS OPERATION LIMITS The STM901-30 power module should never be operated under any condition which exceeds the Absolute Maximum Ratings presented on this data sheet. Nor should the module be operated continuously at any of the specified maximum ratings. If the module is to be operated under any condition such that it may be subjected to one or more of the maximum rating conditions, care must be taken to monitor other parameters which may be affected. DECOUPLING Failure to properly decouple any of the voltage supply pins will result in oscillations at certain operating frequencies. Therefore, it is recommended that these pins be bypassed as indicated in the Module DC and Test Fixture Configuration drawing of this data sheet. MODULE MOUNTING To insure adequate thermal transfer from the module to the heatsink, it is recommended that a satisfactory thermal compound such as Dow Corning 340, Wakefield 120-2 or equivalent be applied between the module flange and the heatsink. THERMAL CONSIDERATIONS It will be necessary to provide a suitable heatsink in order to maintain the module flange temperature at or below the maximum case operating temperature. In a case where the module output power will be limited to +44.7 dBm (30W PEP) and designing for the worst case double-tone efficiency of 25%, the power dissipated by the module will be 48 watts. The heatsink must be designed such that the thermal rise will be less than the difference between the maximum ambient temperature at which the module will operate and the maximum operating case temperature of the module while dissipating 48 watts. At Tcase = +85°C, V = 26v, IQ1 = 0.1A, IQ2 = 0.18A, IQ3 = 0.05A, I Q4 = 0.2A, Z L = 50 ohms and POUT = +44.7dBm PEP, maximum junction temperatures for the individual transistors should be below the following values: Q1 = Q2 = Q3 = Q4 = 115°C 130°C 125°C 145°C The heatsink mounting surface under the module should be flat to within +/- 0.05 mm (+/- 0.002 inch). The module should be mounted to the heatsink using 3 mm (or 4-40) or equivalent screws torqued to 5-6 kg-cm (4-6 in-lb). The module leads are attached to the equipment PC board using 180°C solder applied to the leads with a properly grounded soldering iron tip, not to exceed 195°C, applied a minimum of 2 mm (0.080 inch) from the body of the module for a duration not to exceed 15 seconds per lead. It is imperative that no other portion of the module, other than the leads, be subjected to temperatures in excess of 100°C (maximum storage temperature), for any period of time, as the plastic moulded cover, internal components and sealing adhesives may be adversely affected by such conditions. Due to the construction techniques and the materials used within the module, reflow soldering of the flange heatsink or the leads, is not recommended. October 31, 1997 7/8 STM901-30 PACKAGE MECHANICAL DATA UDCS No. 1010946 rev D Informati on furni shed is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsibili ty for the consequences of use of such information nor for any infringement of patents or other rights of thir d parties w hic h may result from its use. No lic ense is granted by impli cation or otherwise under any patent or patent rights of SGS-THOMSON Mi croelectr onics. Specificati ons mentioned i n this publication are subject to change without notice. T his publication supersedes and replaces all information pr eviously supplied. SGS-T HOMSON Mi croelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of SGS-THOMSON Mi croelectronics. 1997 SGS -T HOMSON Microelectronics - All Rights Reserved SGS-THOMSON Microelectronics GROUP OF COMPANIES Australia - Br azil - Canada - China - F rance - Germany - Italy - Japan - Korea Malaysia - Malta - Morocco - The Netherl ands - Singapor e - Spain - Sweden - Switzerland Taiwan - Thailand - United Kingdom - U.S.A. RF Products Division 141 Commerce Drive Montgomeryville, PA 18936 tel 215-361-6400 fax 215-362-1293 8/8 October 31, 1997