LM5060EVAL/NOPB

User's Guide SNVA413C – October 2009 – Revised May 2013 AN-2000 LM5060EVAL Evaluation Board 1 Introduction The LM5060 evaluation board is designed to demonstrate the capabilities of the LM5060 high side protection controller with low quiescent current. It is intended for evaluation of the functions of the LM5060. One high side N-channel power MOSFET is used. The LM5060 evaluation board schematic is shown in Figure 7. The evaluation board is designed to highlight applications with a small solution size. For more information about LM5060 functional and electrical characteristics, see the LM5060 High-Side Protection Controller With Low Quiescent Current Data Sheet (SNVS628). 2 Operating Range • • • • • Maximum Input Voltage, OVP: 37 V Minimum Input Voltage, UVLO: 9 V Output Current Range: 0A to 5.0A Ambient Temperature Range 0°C to 50°C Board Size 1.35in x 2.25in To aid in the design and evaluation of high-side protection controller solutions based on the LM5060, the evaluation board can be re-configured for different input voltage ranges by modifying the under-voltage lock-out (UVLO) and the over-voltage protection (OVP) resistive divider (R1, R2, and R3) as well as the protection transient voltage suppressor diode D1. The load current capability may be increased above 5A of by changing the value of resistor R4. The PCB layout has not been tested for currents above 5A, so this should only be done with some degree of caution. Typical evaluation board performance and characteristics curves are shown in Figure 1 through Figure 5. The PCB layout is shown in Figure 9 and Figure 10. Test points are provided to enable easy connection and monitoring of critical signals. 3 Evaluation Board Start-Up Before applying power to the LM5060 evaluation board, all external connections should be verified. The external power supply must be turned off and connected with proper polarity to the INPUT and GND posts. A load resistor should be connected between the OUTPUT and GND posts as desired. A resistive load keeps the current through Q1 during turn-on relatively low. Electronic load equipment tends to be very low impedance during voltage rise so that the transistor Q1 will see very high currents during turn-on when using such loads. Though resistive loads are suggested for use with the LM5060 evaluation board, electronic loads can be used with caution as well. The output voltage can be monitored with a multi-meter or oscilloscope at the OUTPUT post. Once all connections to the evaluation board have been verified, input power can be applied. A load resistor or electronic load does not require connection during startup. If the EN test point is pulled high (see the threshold voltage in the Electrical Characteristics section of the LM5060 High-Side Protection Controller With Low Quiescent Current Data Sheet (SNVS628)), the output voltage will ramp up when an input voltage is applied. For the evaluation board to start up, the EN pin needs to be pulled high. A lab cable is required from the EN pin to the VIN pin or other voltage source higher than 2.0 V. All trademarks are the property of their respective owners. SNVA413C – October 2009 – Revised May 2013 Submit Documentation Feedback AN-2000 LM5060EVAL Evaluation Board Copyright © 2009–2013, Texas Instruments Incorporated 1 Inductive Kick-Back Protection www.ti.com Make sure that the external power supply (input voltage power source) is capable of providing enough current to the output load so that the output voltage can be obtained. Figure 1. Start-Up Waveforms Figure 2. Start-Up Waveforms 4 Inductive Kick-Back Protection Diode D1 and capacitor C4 serve as inductive kick protection to limit voltage spikes generated when shutting down high currents through Q1 when turning the power MOSFET off. Capacitor C5 is useful for preventing negative voltages on the OUTPUT trace as the MOSFET Q1 is turned off. 5 Enable The EN test point provided on the LM5060 evaluation board is used to control the LM5060 operation. To shut down the LM5060 evaluation board apply a voltage less than 0.8 V to the EN pin, connect to ground, or open the connection. To start up the LM5060 evaluation board apply a voltage greater than 2.0 V to the EN connection, or connect to VIN directly. If the EN test point is left open, the EN pin internal pull-down will ensure that the LM5060 remains Off. For more details, see the LM5060 High-Side Protection Controller With Low Quiescent Current Data Sheet (SNVS628). 2 AN-2000 LM5060EVAL Evaluation Board SNVA413C – October 2009 – Revised May 2013 Submit Documentation Feedback Copyright © 2009–2013, Texas Instruments Incorporated Under-Voltage Lock-Out (UVLO) www.ti.com 6 Under-Voltage Lock-Out (UVLO) Resistors R1, R2, and R3 set the UVLO from the scaled down value of the input voltage. The LM5060 evaluation board is set to engage UVLO at an input voltage between typically 8.0 V (low threshold) and 8.8 V (high threshold). UVLO is activated when the UVLO pin drops below the high threshold. When UVLO is activated (input voltage is low), the LM5060 turns off MOSFET Q1 but the LM5060 is not latched off. As soon as the UVLO voltage is returned to levels above the high threshold, regular operation will resume. 7 Over-Voltage Protection (OVP) Resistors R1, R2, and R3 also set the OVP level from the scaled value of the input voltage. The resistors on the LM5060 evaluation board are selected to engage OVP when the input voltage rises above 37.1 V (typical). When OVP is engaged, the LM5060 turns off MOSFET Q1 but the LM5060 is not latched off. As the input voltage reduces below 32.8 V (typical), the MOSFET Q1 will turn back on and the output voltage will go up. Figure 3. OVP Behavior Figure 4. RS vs IDSTH for RDS(ON) = 25 mΩ SNVA413C – October 2009 – Revised May 2013 Submit Documentation Feedback AN-2000 LM5060EVAL Evaluation Board Copyright © 2009–2013, Texas Instruments Incorporated 3 Over-Current Protection 8 www.ti.com Over-Current Protection The 9.09 kΩ resistor on the SENSE pin (RS), along with the 0.025Ω of the MOSFET RDS(ON) sets the typical over-current threshold (IDSTH) to approximately 5.8A. This may vary from a low of 4.6A to a high of 6.9A depending on variations in the sense current and the VDS comparator offset voltage. For typical performance for a MOSFET having RDS(ON) of 25 mΩ, see Figure 4. The 0.10 µF timer capacitor will provide a typical over-current fault detection delay time of 18.2 ms. This may vary from a low of 15.4 ms to a high of 23.5 ms depending on variations in the timer charge current and the timer threshold voltage. 9 Output Status (nPGD) The output status can be measured at the STATUS connection on the LM5060 evaluation board. The signal will be high when the LM5060 is in a fault condition (SENSE > OUT). STATUS will be low when the LM5060 is activated and not in a fault state (SENSE < OUT). When the LM5060 is shut down by pulling the EN pin low, the nPGD comparator is shut down and the STATUS signal goes high. Figure 5. Fault Behavior 10 Gate Circuitry C3 is optional and can be used to slow down gate transitions for evaluation. 11 Timer Setting The capacitor C1 sets the start-up time delay, transition time delay, and the Over-Current fault detection delay time. If the voltage on the TIMER cap exceeds the 2.0 V threshold condition, the LM5060 will latch off the MOSFET Q1 and remain off until either the EN, UVLO or VIN (POR) input is switched low and then high. The 0.10 µF(100 nF) timer capacitor will provide a typical start-up delay time of 33.3 ms, a typical transition delay time of 15.5 ms, and a typical over-current fault detection delay time of 18.2 ms. 12 Component Selection Before changing the default components and for information regarding component selection, see the LM5060 High-Side Protection Controller With Low Quiescent Current Data Sheet (SNVS628). 4 AN-2000 LM5060EVAL Evaluation Board SNVA413C – October 2009 – Revised May 2013 Submit Documentation Feedback Copyright © 2009–2013, Texas Instruments Incorporated Component Selection www.ti.com 10 GATE LM5060MM SENSE 1 VIN 2 OVP 3 UVLO 4 EN 5 9 OUT 8 nPGD 7 TIMER 6 GND Figure 6. Connection Diagram Q1 INPUT R4 9.09 k: 1 SENSE + D1 R6 100 k: 51V STATUS EN C4 22 PF High = Fault, Low= OK R1 200 k: C2 0.1 µF OUTPUT R5 0.0 C3 10 GATE 9 OUT 2 VIN + C5 22 PF LM5060 R2 38.3 k: 4 UVLO R3 14.0 k: 3 OVP TIMER 7 8 nPGD C1 0.1 PF GND 6 High = On, Low= Off 5 EN GND GND Figure 7. Schematic Diagram SNVA413C – October 2009 – Revised May 2013 Submit Documentation Feedback AN-2000 LM5060EVAL Evaluation Board Copyright © 2009–2013, Texas Instruments Incorporated 5 x x xx x xx x x Component Selection x GND x Q1 D1 R2 C2 R6 C5 R5 R3 STATUS U1 GND. OUTPUT R1 R4 EN x x x xx x xx x x x x xx x x x x C4 INPUT www.ti.com x x x x x x x xx x x x x C1 LM5060EVAL C3 Figure 8. Component Placement Figure 9. Evaluation Board, Top Side (Component) 6 AN-2000 LM5060EVAL Evaluation Board SNVA413C – October 2009 – Revised May 2013 Submit Documentation Feedback Copyright © 2009–2013, Texas Instruments Incorporated Bill of Materials (BOM) www.ti.com Figure 10. Evaluation Board, Bottom Side 13 Bill of Materials (BOM) ID Description Manufacturer Part Number U1 LM5060 Texas Instruments LM5060 C1 Capacitor: 0.1 µF; 50 V; ±10%; X7R; MLCC; 0603 TDK Corporation C1608X7R1H104K C2 Capacitor: 0.1 µF; 100 V; ±10%; X7R; MLCC; 0805 TDK Corporation C2012X7R2A104K C3 (Not Installed) n/a n/a C4 Capacitor: 22 µF; 100 V; Aluminum Electrolytic; SMT Panasonic - ECG EEE-HA2A220P D1 Diode: TVS; 600W; 51 V; SMB Diodes Inc SMBJ51A-13-F Q1 MOSFET: N-Channel; 100 V; 40A; 0.025Ω; D2PAK Vishay/Siliconix SUM40N10-30-E3 R1 Resistor: 200 kΩ; 0.10W; ±5%; Thick Film; 0603 Vishay/Dale CRCW0603200KJNEA R2 Resistor: 38.3 kΩ; 0.10W; ±1%; Thick Film; 0603 Vishay/Dale CRCW060338K3FKEA R3 Resistor: 14.0 kΩ; 0.10W; ±1%; Thick Film; 0603 Vishay/Dale CRCW060314K0FKEA R4 Resistor: 9.09 kΩ; 0.10W; ±1%; Thick Film; 0603 Vishay/Dale CRCW06039K09FKEA R5 Resistor: 0.00Ω; 0603 Vishay/Dale CRCW06030000Z0EA R6 Resistor: 100 kΩ; 0.10W; ±1%; Thick Film; 0603 Vishay/Dale CRCW0603100KFKEA Terminal: 6-32 Screw; Vertical; Snap-In PCB Mount; 15A Keystone Electronics 7693 Test Point Terminal: PCB Miniature; 0.040in Dia Mtg Hole; White Keystone Electronics 5002 C5 INPUT OUTPUT GND GND. 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