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CS5106LSW24 Datasheet(PDF) 11 Page - Cherry Semiconductor Corporation |
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CS5106LSW24 Datasheet(HTML) 11 Page - Cherry Semiconductor Corporation |
11 / 12 page 11 The equivalent down slope at the current sense resistor for this application circuit is: Slope @ R12 = Inductor_Slope ´´´ R12 After choosing R9 and C9 to generate a ramp with a time constant of about 5 times the oscillator period, R10 and R11 can be chosen for the voltage at RAMP2 to be 1.75 of the voltage across R12. Synchronous Rectification Synchronous rectification was chosen to reduce losses in the forward converter. Improvements in efficiency will be most significant in low voltage, medium and high current converters where improvement in conduction loss offsets any added losses for gate drive. In the application circuit Q4 is turned on and off by the for- ward transformer. Q5 is turned on and off through pulse transformer T4 and the gate driver formed by Q6 and Q7. Because Q4 and Q5 are driven through different types of components, differences in propagation delay must be con- sidered. The DLYSET resistor should be chosen to avoid shoot-through or excessive off time. Gate Drive Capability All GATE drive outputs have nominal peak currents of 0.5A. See Figures 6 and 7 for typical rise and fall times. Figure 6: Typical GATE2, 2B switching times. Figure 7: Typical GATE1 switching times. Design Considerations The circuit board should utilize high frequency layout techniques to avoid pulse width jitter and false triggering of high impedance inputs. Ground plane(s) should be employed. Signal grounds and power grounds should be run separately. Portions of the circuit with high slew rates or current pulses should be segregated from sensitive areas. Shields and decoupling capacitors should be used as required. Special care should be taken to prevent coupling between the SYNC leads and the surrounding leads. Depending on the circuit board layout and component values, decoupling capacitors or reduction in resistor values might be required to reduce noise pick-up on the FADJ and DLYSET resistors. Decoupling capacitors or active pull-up/down might be required to prevent false triggering of the ENABLE and PROGRAM leads. Load Capacitance (pF) 60 50 40 30 20 10 0 50 Rise Time Fall Time 70 1500 500 1000 2000 200 Load Capacitance (pF) 70 60 50 40 30 20 10 0 Rise Time Fall Time 50 100 500 1000 2000 200 ) V µs ( NPT3 NST3 NST2 NPT2 Theory of Application: continued |
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