Ordering number: EN2885A Thick Film Hybrid IC STK4432 AF Power Amplifier (25W + 25W min, THD = 1.0%) Features Package Dimensions • Small and slim package with 31 mm height • Pin compatible with STK430 series heretofore in use • Greatly reduced heat sink due to case temperature 125°C guaranteed • Excellent cost performance unit: mm 4033 [STK4432] Specifications Maximum Ratings at Ta = 25°C Parameter Symbol Maximum supply voltage Conditions Ratings Unit VCC max 70 V Tc 125 °C −30 to +125 °C 2 s Operating substrate temperature Storage temperature Tstg Available time for load short-circuit ts VCC = 49V, RL = 8Ω, f = 50Hz, Po = 25W Recommended Operating Conditions at Ta = 25°C Parameter Symbol Conditions Ratings Unit Recommended operating voltage VCC 49 V Load resistance RL 8 Ω Operating Characteristics at Ta = 25°C, VCC = 49V, RL = 8Ω, Rg = 600Ω, VG = 40dB Parameter Quiescent current Symbol Icco Frequency response Input impedance Output noise voltage min typ Unit 120 mA 20 Po (1) THD = 1.0%, f = 1kHz 25 W Po (2) THD = 1.0%, f = 30Hz to 20kHz 13 W THD Po = 0.1W, f = 1kHz fL, fH +0 Po = 0.1W, dB −3 ri VNO Po = 0.1W, f = 1kHz VCC = 58V, Rg = 10kΩ 60 max VCC = 58V Output power Total harmonic distortion Conditions 0.3 % 20 to 100k Hz 110 kΩ 0.8 mVrms SANYO Electric Co., Ltd. Semiconductor Business Headquarters TOKYO OFFICE Tokyo Bldg., 1-10, 1 Chome, Ueno, Taito-ku, TOKYO, 110 JAPAN 110297HA (ID) / 9088TA, TS No. 2885—1/7 STK4432 Notes. For power supply at the time of test, use a constant-voltage power supply unless otherwise specified. For measurement of the available time for load short-circuit and output noise voltage, use the specified transformer power supply shown right. The output noise voltage is represented by the peak value on rms scale (VTVM) of average value indicating type. For AC power supply, use an AC stabilized power supply (50Hz) to eliminate the effect of flicker noise in AC primary line. Specified Transformer Power Supply (Equivalent to RP-25) Equivalent Circuit Sample Application Circuit: 25W min 2-Channel AF Power Amplifier No. 2885—2/7 STK4432 Output power, Po - W Total harmonic distortion, THD - % Sample Printed Circuit Pattern for Application Circuit (Cu-foiled side) Output power, Po - W Voltage gain, VG - dB Output power, Po - W Input voltage, Vi - mV Frequency, f - Hz Frequency, f - Hz No. 2885—3/7 Voltage gain, VG - dB Supply voltage, VCC - V IC Power dissipation, Pd - W Output power, Po - W Current drain, ICC - A Quiescent current, Icco - mA Quiescent current, Icco - mA STK4432 Operating substrate temperature, Tc - °C Supply voltage, VCC - V Output power, Po - W Frequency, f - Hz No. 2885—4/7 STK4432 Description of External Parts C1, C2 Input filter capacitors • A filter formed with R1 or R2 can be used to reduce noise at high frequencies. C3, C4 Input coupling capacitors • Used to block DC current. When the reactance of the capacitor increases at low frequencies, the dependence of 1/f noise on signal source resistance causes the output noise to worsen. It is better to decrease the reactance. NF capacitors • These capacitors fix the low cutoff frequency shown below. C5, C6 C15 R7, R8 R11 1 f L = ----------------------------------- Hz 2π ⋅ C5 ⋅ R3 To provide the desired voltage gain at low frequencies, it is better to increase C5. However, do not increase C5 more than needed because the pop noise level becomes higher at the time of application of power. Capacitor for ripple filter • Used to eliminate the ripple components that mix into the input side from the power line (+VCC). Front stage bias resistors Front stage bias resistor C9, C10 Oscillation blocking capacitors • A polyester film capacitor, being excellent in temperature characteristic, frequency characteristic, is recommended for C9, C10. R1, R2 Resistors for input filter R12 Front stage bias resistor R3, R5 (R4, R6) These resistors fix voltage gain VG. It is recommended to use R3 (R4) = 12Ω for VG = 40dB. • To adjust VG, it is desirable to change R3 (or R4). C7, C8 Bootstrap capacitors • When the capacitor value is decreased, the distortion is liable to be higher at low frequencies. R13 C11, C12 Resistor for ripple filter (Limiting resistor for predriver TR at the time of load short) Output capacitors • These capacitors fix the low cutoff frequency. C13 Oscillation blocking capacitor • Must be inserted as close to the IC power supply pins as possible so that the power supply impedance is decreased to operate the IC stably. C14 Decoupling capacitor • When the capacitor value is increased, the starting time is made longer. R9, R10 Oscillation blocking resistors No. 2885—5/7 STK4432 Sample Application Circuit (protection circuit and muting circuit) The IC power dissipation of the STK4432 at the IC-operated mode is 30W max. at load resistance 8Ω (simultaneous drive of 2 channels) for continuous sine wave as shown in Figure 1. In an actual application where a music signal is used, it is impractical to estimate the power dissipation based on the continuous signal as shown right, because too large a heat sink must be used. It is reasonable to estimate the power dissipation as 1/10 Po max. (EIAJ). That is, Pd = 21.5W at 8Ω Thermal resistance θc-a of a heat sink for this IC power dissipation (Pd) is fixed under conditions 1 and 2 shown below. IC Power dissipation, Pd - W Thermal Design Output power, Po - W Figure 1. STK4432 Pd – Po (RL = 8Ω) Condition 1: TC = Pd × θc-a + Ta ≤ 125°C .............................................. (1) where Ta : Specified ambient temperature TC : Operating substrate temperature Condition 2: Tj = Pd × (θc-a) + Pd/4 × (θj-c) + Ta ≤ 150°C .................... (2) where Tj : Junction temperature of power transistor Assuming that the power dissipation is shared equally among the four power transistors(2 channels × 2), thermal resistance θj-c is 2.8°C/W and Pd × (θc-a + 2.8/4) + Ta ≤ 150°C........................................ (3) No. 2885—6/7 Thermal resistance θc-a of a heat sink must satisfy inequalities (1) and (3). Figure 2 shows the relation between Pd and θc-a given from (1) and (3) with Ta as a parameter. [Example] The thermal resistance of a heat sink is obtained when the ambient temperature specified for a stereo amplifier is 50°C. Assuming VCC = 49V, RL = 8Ω, RL = 8Ω : Pd = 21.5W at 1/10 Po max. The thermal resistance of a heat sink is obtained from Figure 2. RL = 8Ω : θc-a = 3.49°C/W Tj when a heat sink is used is obtained from (3). RL = 8Ω : Tj = 140.1°C Thermal resistance of heat sink, θc-a - °C/W STK4432 IC Power dissipation, Pd - W Figure 2. STK4432 θc-a – Pd ■ No products described or contained herein are intended for use in surgical implants, life-support systems, aerospace equipment, nuclear power control systems, vehicles, disaster/crime-prevention equipment and the like, the failure of which may directly or indirectly cause injury, death or property loss. ■ Anyone purchasing any products described or contained herein for an above-mentioned use shall: Accept full responsibility and indemnify and defend SANYO ELECTRIC CO., LTD., its affiliates, subsidiaries and distributors and all their officers and employees, jointly and severally, against any and all claims and litigation and all damages, cost and expenses associated with such use: Not impose any responsibility for any fault or negligence which may be cited in any such claim or litigation on SANYO ELECTRIC CO., ➁ LTD., its affiliates, subsidiaries and distributors or any of their officers and employees, jointly or severally. ➀ ■ Information (including circuit diagrams and circuit parameters) herein is for example only; it is not guaranteed for volume production. SANYO believes information herein is accurate and reliable, but no guarantees are made or implied regarding its use or any infringements of intellectual property rights or other rights of third parties. This catalog provides information as of November, 1997. Specifications and information herein are subject to change without notice. No. 2885—7/7