DEMO MANUAL DC1627A LTC4226 Wide Operating Range Dual Hot Swap Controller Description Demonstration circuit 1627A is intended to display the Hot SwapTM functionality of the LTC(R)4226 wide operating range dual Hot Swap controller. The DC1627A has two independent circuits, each for two rails. The circuit placed on the upper board area is for a high current load. The first channel of the upper board circuit operates with a 10A maximum in the +12V rail while the second channel operates with a 5A maximum in the +5V rail. Provision is made for the installation of several MOSFET packages to test the LTC4226's performance during a short time with the larger current. Circuit LEDs indicate a presence of the input rail voltages and fault conditions in each rail. There are two jumpers: one for the current limit multiplicity selection and the other one for overvoltage protection configuration. The circuit located on the lower board area is a special compact circuit for the Apple FireWire/IEEE 1394 power distribution. Performance Summary SYMBOL PARAMETER Both channels of this circuit operate with a 1.25A maximum current in the 12V rails. It is not recommended to use this circuit for other operating conditions. There are two versions of the controller: LTC4226-1 and LTC4226-2. The LTC4226-1 remains off after a fault while the LTC4226-2 automatically retries after a 0.5 second delay. The DC1627A allows estimating the performance of the LTC4226 in different operation modes such as ramp-up, steady-state, and overcurrent fault conditions. Design files for this circuit board are available at http://www.linear.com/demo L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks and Hot Swap is a trademark of Linear Technology Corporation. All other trademarks are the property of their respective owners. Specifications are at TA = 25C CONDITIONS MIN TYP MAX UNITS 9.79 12 16 V 9.15 9.79 10.53 V 15.4 16 17 Upper Circuit +12V Channel VCC1 Input Supply Range VCC1(UV) Input Supply Undervoltage VCC Rising; Based on the ON1 Pin Threshold VCC1(OV) Input Supply Overvoltage VCC Rising S1 Output Voltage Slew Rate No Current Limit ICB1 Circuit Breaker Current Limit 12000 8.91 V V/s 10 11.11 A tCB1 Timer Period During Circuit Breaker Operation 19 29 48 ILIM1 Current Limit by Current Limit (CL) Amplifier CLS = 0V (1.5x) CLS = Open (2x) CLS = 3V (3x) 13.86 18.42 38.2 17.2 23 34.6 20.80 27.47 41.4 ms A A A tFTMR1 Fault Timer Period During CL operation CLS = 0V (1.5x) CLS = Open (2x) CLS = 3V (3x) 2 1.12 0.5 2.9 1.6 0.7 4.6 2.6 1.15 ms ms ms 4.11 5 7.3 V Upper Circuit +5V Channel VCC2 Input Supply Range VCC2(UV) Input Supply Undervoltage VCC Rising; Based on the ON2 Pin Threshold 3.86 4.11 4.37 V VCC2(OV) Input Supply Overvoltage VCC Rising 6.8 7.3 7.7 V S2 Output Voltage Slew Rate No Current Limit 12000 V/s dc1627af 1 DEMO MANUAL DC1627A Performance Summary SYMBOL PARAMETER ICB2 Circuit Breaker Current Limit Specifications are at TA = 25C CONDITIONS MIN TYP MAX UNITS 4.45 5 5.55 A tCB2 Timer Period During Circuit Breaker Operation 39 50 80 ILIM2 Current Limit by CL Amplifier CLS = 0V (1.5x) CLS = Open (2x) CLS = 3V (3x) 6.9 9.2 13.8 8.6 11.5 17.3 10.4 13.7 20.7 ms A A A tFTMR2 Fault Timer Period CLS = 0V (1.5x) CLS = Open (2x) CLS = 3V (3x) 3.3 1.9 0.8 5.1 2.8 1.3 8.4 4.7 2.1 ms ms ms 16.7 V V Compact Circuit for FireWire Power Distribution VCC Input Supply Range Based on the ON Pin Threshold 4.62 VCC(UV) Input Supply Undervoltage VCC Rising 4.62 4.96 5.28 ICB Circuit Breaker Current Limit 1.35 1.51 1.68 A tCB Timer Period During Circuit Breaker Operation 6.07 9.2 15.3 ms ILIM Current Limit by CL Amplifier CLS = 0V (1.5x) CLS = Open (2x) CLS = 3V (3x) 2.1 2.8 4.2 2.6 3.5 5.3 3.2 4.2 6.3 A A A tFTMR Fault Timer Period CLS = 0V (1.5x) CLS = Open (2x) CLS = 3V (3x) 0.6 0.35 0.15 0.9 0.5 0.25 1.6 0.9 0.39 ms ms ms Operating Principles The LTC4226 controls two rails with external N-channel MOSFETs. Two independent ONn comparators allow ramping rails up and down independently. active current limiting. By this means, the timer period during an active current limit is ten times less than it is in the circuit breaker operation. During normal operation, the charge pump delivers 9A to the gate driver to turn on the external N-channel MOSFET. The LTC4226-1 latches off after the MOSFET is turned off under an overcurrent condition. The ON pin status must be recycled low to high for the gate drive to restart. The demo board with LTC4226-1 is labeled as DC1627A-A. Each channel's circuit breaker (CB) comparator and current limit (CL) amplifier monitor the load current using the sense resistor voltage between the VCCn and the SENSEn pins. When the sense resistor voltage exceeds circuit breaker threshold (VCB), (but lower than VLIMIT) the CB comparator enables a 2A current source, and the voltage at the fault timer (FTMRn) capacitor ramps up. When the FTMRn comparator voltage reaches 1.23V threshold, the corresponding MOSFET is turned off. When the sense resistor voltage exceeds VLIMIT, the CL amplifier limits the current in the load by reducing the gate-to-out voltage in an active control loop. The fast response CL amplifier can quickly adjust the gate-to-out voltage in the event of an output-to-ground short circuit. The FTMRn capacitor voltage ramps up with a 20A (or 36A, or 80A) current source instead of the 2A in the The LTC4226-2 automatically retries after an overcurrent condition. It begins with a 0.5 second delay before resetting the fault timer with a 100A pull-down, followed by gate restart if ON pin is high. The demo board with LTC4226-2 is labeled as DC1627A-B. Both channels share a common current limit select functionality with the current limit select (CLS) pin signal. This signal can have three input states: low, open and high. The three input states correspond to the preset current limit values. VLIMIT becomes 1.5x, or 2.0x, or 3.0x of 1.15x VCB. Undervoltage protection in the upper circuit is based on the ONn pin threshold. The resistors of each ONn pin divider are selected to have a threshold voltage at the LTC4226 ON dc1627af 2 DEMO MANUAL DC1627A Operating Principles pin, when the input voltage equals the defined minimum. The Performance Summary table shows their values with consideration for the voltage tolerance of the comparator threshold and for 1% resistor tolerance. on the FTMR capacitor can be found. It lowers the time in current limit mode. Overvoltage protection levels shown in the Performance Summary table were obtained by simulation. Overvoltage protection in the upper circuit is built with Zener and Schottky diodes to trigger an artificial overcurrent mode by charging the FTMR capacitor. Due to the peculiar current leakage of some devices and their sensitivity to higher temperature a small initial voltage (0.1V to 0.2V) Inherent in the LTC4226 is an undervoltage protection feature that allows the channels to operate only if VCC is above 3.7V. When VCC rises above the undervoltage lockout level, there is a delay of 50ms before the gate starts to ramp. Quick Start Procedure The test procedure for each channel of the LTC4226 is identical and includes verification of the main circuit parameters: S1-S2 output voltage slew rate; n ICB1-ICB2 circuit breaker level performed by the circuit breaker and fault timer period (FTMR), when an overcurrent mode is initiated after power up has been completed; n ICL1-ICL2 the current limit level performed by the current limit amplifier and fault timer period (FTMR) with an initially shorted output and CLS pin grounded. n If there is a need to test a channel with rail voltages other than those used for the DC1627A design (+5V, and +12V), make changes to the appropriate ON pin signal divider (R5, R10, R12 for channel 1 or R23, R29, and R31 for channel 2). If any LTC4226 channel should operate at other than a factory assigned current, change the value of the sense resistor (R2, R22) and select the desired position for the current limit selection (CLS) jumper. Verify the power MOSFET current capability in the steady-state and in the power-up modes. Replace Q1 or Q3 with a suitably packaged MOSFET. Demonstration circuit DC1627A is easy to set up to evaluate the performance of the each LTC4226 Hot Swap channel. Refer to Figure 1 for the proper measurement equipment setup for one channel and follow the procedure listed next. UPPER CIRCUIT TEST Jacks and Joined Turrets n n n n n n n n J1 (VCC1): 12V supply input; do not exceed 35V J2 (GND): Ground connection for 12V input supply J3 (OUT1): Output for 12V rail J4 (GND): Ground connection for 12V output J5 (VCC2): 5V supply input; do not exceed 35V J6 (GND): Ground connection for 5V input supply J7 (OUT2): Output for 5V rail J8 (GND): Ground connection for 5V output Turrets Connected to Controller Pins n n n n n n n n E3 (ON1) E4 (FTMR1) E5 (CLS) E6 (FAULT1) E7 (FAULT2) E8 (FTMR2) E11 (ON2) E26 (DCLA) Jumpers JP1 (CLS): Current limit selection: Use 1.5X position to have 1.725X circuit breaker current limit (CBCL); use 2X position to have 2.3X CBCL; use 3X position to have 3.45X CBCL. dc1627af 3 DEMO MANUAL DC1627A Quick Start Procedure JP2 (OVBLK): Overvoltage blocking selection: Use SEP position for individual channel blocking under overvoltage condition; use BOTH position for both channel blocking under any channel's overvoltage condition. LEDs n n n n D3 (green): +12V supply is present D15 (green): +5V supply is present D7 (red): +12V channel fault D9 (red): +5V channel fault +12V Hot Swap As the test procedures for all LTC4226 channels are identical, the following detailed description of the steps for +12V channel test can be used for the other DC1627's channels with the only difference being the mentioned component designators. 1.The jumpers' shunts should be placed in the following position: JP1 (CLS) 1.5x JP2 (OVBLK) SEP Connect ON1 and GND turrets with an external wire to disable the +12V Hot Swap circuit. 2.Connect the +12V supply terminals to the +12V and GND demo board jacks appropriately and place scope probes on the OUT1 and FTMR1 turrets and a current probe to measure the +12V wire current. Turn on the +12V supply. +12V green LED (D3) will light indicating the presence of input voltage. Disconnect the ON1 and GND turrets to provide an ON1 pin signal, and verify that the output voltage rises in less than 1ms. 3.Keep the scope probes and current probe in the same place. Initiate +12V channel operation with no load, gradually increasing the load current with an electronic or resistive load and verify that the circuit breaker is in the range of 8.9A to 11.11A and the timer period is between 19ms and 48ms. Disable the +12V channel by connecting the ON1 and GND turrets. 4.With the +12V channel disabled, short the output to GND with an external wire. Monitor the current in the shorting wire with a current probe. Place the scope probes on the VCC1 and FTMR1 turrets. Enable the channel with an ON1 pin signal and verify that current is limited in the range 13.86A to 20.8A and current limit mode takes from 2ms to 4.6ms. The upper circuit provides options for current limit selection (CLS JP1) and overvoltage protection (JP OVBLK). Three positions of the current limit selection (CLS) jumper (JP1) correspond with the three pair of current limit parameters: current level and timer period. Estimated values for these parameters are shown in the Performance Summary table. Special attention should be given to verification of the MOSFET's SOA regarding these parameters. 5.Each channel's overvoltage protection circuit can block its own channel if the OVBLK jumper header is installed in the position SEP, or both channels if the OVBLK is in the position BOTH. The +12V rail overvoltage protection is in the 15.4V to 17V range, and +5V rail is in the 6.8V to 7.7V range. To test the overvoltage protection level place a scope probe at the FTMR turret and start to gradually increase the input voltage. The protection level is estimated when FTMR voltage reaches threshold and drops low. It means that an auxiliary overcurrent mode has been generated. +5V Hot Swap 6. The jumpers' shunts should be placed in the following position: JP1 (CLS) 1.5x JP2 (OVBLK) SEP Connect ON2 and GND turrets with an external wire to disable the +5V Hot Swap circuit. dc1627af 4 DEMO MANUAL DC1627A Quick Start Procedure 7. Connect the +5V supply terminals to the +5V and GND demo board jacks appropriately and place scope probes on the OUT2 and FTMR2 turrets and current probe to measure the +5V wire current. Turn on the +5V supply. +5V green LED (D15) will light up indicating the presence of input voltage. Disconnect the ON2 and GND turrets to provide an ON2 pin signal, and verify that the output voltage rises in less than 1ms. 8. Keeping the scope probes and current probe in the same place, initiate +5V channel operation with no load, gradually increasing the load current with an electronic or resistive load and verify that the circuit breaker is in the range of 4.45A to 5.55A and timer period is from 39ms to 80ms. Disable the +5V channel by connecting the ON2 and GND turrets. 9. With the +5V channel disabled, short the output to GND with an external wire. Monitor the current in the shorting wire with a current probe. Place the scope probes on the VCC2 and FTMR2 turrets. Enable the channel with an ON2 pin signal and verify that current is limited in the range of 6.9A to 10.4A and current limit mode takes from 3.3ms to 8.4ms. 10.Confirm that each position of the current limit jumper corresponds to the appropriate current limit level and timer period. Special attention should be given to verification of the MOSFET's SOA regarding these parameters. COMPACT CIRCUIT TEST Turrets n n n n E1 and E16: Circuit GND E13: 1st channel +12V supply input; do not exceed 35V E14 (OUT1): 1st channel output E15: 2nd channel +12V supply input; do not exceed 35V E17 (ON1) n E18 (FTMR1) n E19 (CLS) n E20 (FAULT1) n E21 (FAULT2) n E22 (FTMR2) n E23 (ON2) n E24 (OUT2) Connect ON1 and GND turrets with an external wire to disable the +12V hot swap circuit. Connect CLS and GND turrets to select the lowest CL level. n 1.Connect the +12V supply terminals to the +12V and GND demo board turrets. Place scope probes on the OUT1 and FTMR1 turrets and a current probe to measure +12V wire current. 2.Turn on the +12V supply. Disconnect ON1 and GND turrets to provide an ON1 pin signal, and verify that the output voltage rises in less than 1ms. 3.Keeping the scope probes and current probe in the same place, initiate the +12V channel operation with no load, gradually increasing the load current with an electronic or resistive load and verify that the circuit breaker is in the range of 1.35A to 1.68A and timer period 6.1ms to 15.3ms. Disable the +12V channel by connection of the ON1 and GND turrets. 4.With the +12V channel disabled, short the output to GND with an external wire. Monitor the current in the shorting wire with a current probe. Place the scope probes on the VCC1 and FTMR1 turrets. Enable the channel with an ON1 pin signal and verify that current is limited in the range of 2.1A to 3.2A and current limit mode takes 0.6ms to 1.6ms. dc1627af 5 DEMO MANUAL DC1627A Quick Start Procedure Figure 1. DC1627A Measurement Equipment Setup dc1627af 6 DEMO MANUAL DC1627A Parts List ITEM 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 QTY 4 2 2 2 0 1 1 1 2 4 2 2 1 15 14 1 1 8 2 0 2 0 1 2 0 1 1 4 1 0 2 2 2 3 1 1 1 2 2 2 2 2 2 2 2 REFERENCE COUT1, C1, COUT2, C8 CT1, CT2 C2, C9 C3, C12 C4, C5, C10, C11 C6 C7 D2 D3, D15 D4, D6, D8, D10 D5, D12 D7, D9 D13 E3-E8, E11, E17-E23, E26 E1, E13-E16, E24, E25, E27-E33 JP1 JP2 J1, J2, J3, J4, J5, J6, J7, J8 Q1, Q3 Q2, Q4 Q5, Q6 R1, R21 R2 R3, R19 R4, R14, R23, R28 R5 R6 R7, R17, R25, R38 R8 R9, R11, R27, R30 R10, R29 R12, R31 R13, R18 R15, R16, R24 R20 R22 R26 R32, R37 R33, R35 R34, R36 Z1, Z2 Z3, Z4 SHUNTS ON JP1&JP2 U1, U2 U1, U2 PART DESCRIPTION CAP., X7R, 10F 50V, 10%, 1210 CAP., X7R, 15nF, 50V 10%, 0603 CAP., X7R, 0.1F 10% 10V, 0603 CAP., X7R, 0.047F 10% 10V, 0603 CAP., 0603 CAP., X7R, 47nF, 50V 5%, 0603 CAP., X7R, 82nF, 50V 10%, 0603 DIODE ZENER, 1.8V 500mW, 5%, SOD123 LED, GREEN DIODE, FAST SWITCHING, SOD523 DIODE ZENER, 1.8V 500mW, 5%, SOD123 LED, RED, 0603 DIODE ZENER, 1.8V 500mW, 5%, SOD123 TP, TURRET, 0.064" TP, TURRET, 0.094" JMP, 4-PIN, 2mm JMP, 3-PIN, 2mm JACK, BANANA MOSFET, N-CH, POWER56 MOSFET, N-CH, SO8-POWERPAK MOSFET, N-CH, 40V(D-S), SOT23 RES, 1k, 0805 RES, 0.005, 1% 1/4W, 1206 RES, 30.1k, 5% 1/10W, 0603 RES, 0603 RES, 46.4k, 1% 1/10W, 0603 RES, 5.6k, 5% 1/10W, 0603 RES, 10, 5% 1/10W, 0603 RES, 3.3k, 5% 1/10W, 0603 RES, 10, 0603 RES, 23.2k, 1% 1/10W, 0603 RES, 10k, 5% 1/10W, 0603 RES, 2.4M, 5% 1/10W, 0603 RES., CHIP, 0, 0603 RES, 1.8k, 5% 1/10W, 0603 RES, 0.01, 1% 1/4W, 1206 RES, 1k, 5% 1/10W, 0603 RES, 0.033, 1% 1/4W, 1206 RES,150k, 5% 1/10W, 0603 RES, 49.9k, 5% 1/10W, 0603 DIODE, SMC-DIODE DIODE, TRANSIENT VOLTAGE SUPPRESSOR, POWEREDi123 SHUNT, 2mm IC LTC4226CUD-1, DC1627A-A IC LTC4226CUD-2, DC1627A-B MANUFACTURER/PART NUMBER MURATA, GRM32ER71H106KA12L AVX, 06035C153KAT2A AVX, 0603ZC104KAT AVX, 0603ZC473KAT2A OPT AVX, 06035C473JAT2A AVX, 06035C823KAT2A CENTRAL SEMI., CMHZ4701 PANASONIC, LN1351C-(TR) DIODES INC., 1N4448HWT CENTRAL SEMI., CMHZ4683 VISHAY, TLMS1001-GS08 CENTRAL SEMI., CMHZ4690 MILL-MAX, 2308-2-00-80-00-00-07-0 MILL-MAX, 2501-2-00-80-00-00-07-0 SAMTEC, TMM-104-02-L-S SAMTEC, TMM-103-02-L-S KEYSTONE, 575-4 FAICHILD SEMI., FDMS86500DC OPT VISHAY, Si2318CDS OPT VISHAY, WSL12065L000FEA VISHAY, CRCW060330K1JKEA OPT VISHAY, CRCW060346K4FKEA VISHAY, CRCW06035K60JKEA VISHAY, CRCW060310R0JNEA VISHAY, CRCW06033K30JKEA OPT VISHAY, CRCW060323K2FKEA VISHAY, CRCW060310K0JNEA PANASONIC, ERJ-3GEYJ245V VISHAY, CRCW06030000Z0EA VISHAY, CRCW06031K80JKEA VISHAY, WSL1206R0100FEA VISHAY, CRCW06031K00JNEA VISHAY, WSL1206R0330FEA VISHAY, CRCW0603150KJKEA VISHAY, CRCW060349K9JKEA DIODES INC., SMCJ33CA-13-F DIODES INC., DFLT15A SAMTEC, 2SN-BK-G LINEAR TECHNOLOGY CORP LINEAR TECHNOLOGY CORP dc1627af 7 DEMO MANUAL DC1627A Schematic Diagram dc1627af 8 DEMO MANUAL DC1627A Schematic Diagram dc1627af Information furnished by Linear Technology Corporation is believed to be accurate and reliable. However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights. 9 DEMO MANUAL DC1627A DEMONSTRATION BOARD IMPORTANT NOTICE Linear Technology Corporation (LTC) provides the enclosed product(s) under the following AS IS conditions: This demonstration board (DEMO BOARD) kit being sold or provided by Linear Technology is intended for use for ENGINEERING DEVELOPMENT OR EVALUATION PURPOSES ONLY and is not provided by LTC for commercial use. As such, the DEMO BOARD herein may not be complete in terms of required design-, marketing-, and/or manufacturing-related protective considerations, including but not limited to product safety measures typically found in finished commercial goods. As a prototype, this product does not fall within the scope of the European Union directive on electromagnetic compatibility and therefore may or may not meet the technical requirements of the directive, or other regulations. If this evaluation kit does not meet the specifications recited in the DEMO BOARD manual the kit may be returned within 30 days from the date of delivery for a full refund. THE FOREGOING WARRANTY IS THE EXCLUSIVE WARRANTY MADE BY THE SELLER TO BUYER AND IS IN LIEU OF ALL OTHER WARRANTIES, EXPRESSED, IMPLIED, OR STATUTORY, INCLUDING ANY WARRANTY OF MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE. EXCEPT TO THE EXTENT OF THIS INDEMNITY, NEITHER PARTY SHALL BE LIABLE TO THE OTHER FOR ANY INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES. The user assumes all responsibility and liability for proper and safe handling of the goods. Further, the user releases LTC from all claims arising from the handling or use of the goods. Due to the open construction of the product, it is the user's responsibility to take any and all appropriate precautions with regard to electrostatic discharge. Also be aware that the products herein may not be regulatory compliant or agency certified (FCC, UL, CE, etc.). No License is granted under any patent right or other intellectual property whatsoever. LTC assumes no liability for applications assistance, customer product design, software performance, or infringement of patents or any other intellectual property rights of any kind. LTC currently services a variety of customers for products around the world, and therefore this transaction is not exclusive. Please read the DEMO BOARD manual prior to handling the product. Persons handling this product must have electronics training and observe good laboratory practice standards. Common sense is encouraged. This notice contains important safety information about temperatures and voltages. For further safety concerns, please contact a LTC application engineer. Mailing Address: Linear Technology 1630 McCarthy Blvd. Milpitas, CA 95035 Copyright (c) 2004, Linear Technology Corporation dc1627af 10 Linear Technology Corporation LT 0613 * PRINTED IN USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 FAX: (408) 434-0507 www.linear.com LINEAR TECHNOLOGY CORPORATION 2013