MIC2582/MIC2583 Single-Channel Hot Swap Controllers General Description Features The MIC2582 and MIC2583 are single-channel positive voltage hot swap controllers designed to allow the safe insertion of boards into live system backplanes. The MIC2582 and MIC2583 are available in 8-pin SOIC and 16-pin QSOP packages, respectively. Using a few external components and by controlling the gate drive of an external N-Channel MOSFET device, the MIC2582/83 provide inrush current limiting and output voltage slew rate control in harsh, critical power supply environments. Additionally, a circuit breaker function will latch the output MOSFET off if the current-limit threshold is exceeded for a determined period. The MIC2583R option includes an auto-restart function upon detecting an over current condition. MIC2582: Pin-for-pin functional equivalent to the LTC1422 2.3V to 13.2V supply voltage operation Surge voltage protection up to 20V Current regulation limits inrush current regardless of load capacitance Programmable inrush current limiting Electronic circuit breaker Optional dual-level overcurrent threshold detects excessive load faults Fast response to short-circuit conditions (<1s) Programmable output under-voltage detection Undervoltage Lockout (UVLO) protection Auto-restart function (MIC2583R) Power-on-Reset (POR) status output Power good (PG) status output (MIC2583 and MIC2583R) /FAULT status output (MIC2583 and MIC2583R) Datasheets and support documentation are available on Micrel's web site at: www.micrel.com. Applications RAID systems Base stations PC board hot swap insertion and removal +12V backplanes Network switches Typical Application Micrel Inc. * 2180 Fortune Drive * San Jose, CA 95131 * USA * tel +1 (408) 944-0800 * fax + 1 (408) 474-1000 * http://www.micrel.com May 23, 2014 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Ordering Information Part Number Fast Circuit Breaker Threshold Circuit Breaker Package MIC2582-xYM x = J, 100mV x = J1, Off x = M, Off Latched off 8-pin SOIC MIC2583-xYQS x = J, 100mV (1) x = K , 150mV (1) x = L , 200mV (1) x = M , Off Latched off 16-pin QSOP MIC2583R-xYQS x = J, 100mV (1) x = K , 150mV (1) x = L , 200mV (1) x = M , Off Auto-retry 16-pin QSOP Note: 1. Contact factory for availability. Pin Configuration 8-Pin SOIC (M) 16-Pin QSOP (QS) Pin Description Pin Number 8-Pin SOIC 1 2 May 23, 2014 Pin Number 16-Pin QSOP 1 3 Pin Name Pin Function /POR Power-on-Reset output: Open drain N-channel device, active low. This pin remains asserted during start-up until a time period (tPOR) after the FB pin voltage rises above the power good threshold (VFB). The timing capacitor C POR determines tPOR. When the output voltage monitored at the FB pin falls below VFB, /POR is asserted for a minimum of one timing cycle (t POR). The /POR pin requires a pull-up resistor (10k minimum) to VCC. ON ON input: Active high. The ON pin is an input to a Schmitt-triggered comparator used to enable/disable the controller, is compared to a 1.24V reference with 50mV of hysteresis. When a logic high is applied to the ON pin (V ON > 1.24V), a start-up sequence begins and the GATE pin starts ramping up towards its final operating voltage. When the ON pin receives a logic low signal (V ON < 1.19V), the GATE pin is grounded and /FAULT remains high if VCC is above the UVLO threshold. ON must be low for at least 20s after VCC is above the UVLO threshold in order to initiate a start-up sequence. Additionally, toggling the ON pin LOW to HIGH resets the circuit breaker. 2 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Pin Description (Continued) Pin Number 8-Pin SOIC Pin Number 16-Pin QSOP Pin Name 3 4 CPOR 4 7, 8 GND 5 6 7 8 n/a n/a n/a May 23, 2014 12 14 15 16 2 5 11 FB GATE SENSE VCC Pin Function Power-on-Reset timer: A capacitor connected between this pin and ground sets the supply contact start-up delay (tSTART) and the power-on reset interval (tPOR). When VCC rises above the UVLO threshold, and the ON pin is above the ON threshold, the capacitor connected to CPOR begins to charge. When the voltage at CPOR crosses 0.3V, the start-up threshold (VSTART), a start cycle is initiated if ON is asserted while capacitor CPOR is immediately discharged to ground. When the voltage at FB rises above VFB, capacitor CPOR begins to charge again. When the voltage at CPOR rises above the power-on reset delay threshold (VTH), the timer resets by pulling CPOR to ground, and /POR is de-asserted. If CPOR is left open, then tSTART defaults to 20s. Ground connection: Tie to analog ground. Power good threshold input (Undervoltage detect): This input is internally compared to a 1.24V reference with 30mV of hysteresis. An external resistive divider may be used to set the voltage at this pin. If this input momentarily goes below 1.24V, then /POR is activated for one timing cycle, tPOR, indicating an output undervoltage condition. The /POR signal de-asserts one timing cycle after the FB pin exceeds the power good threshold by 30mV. A 5s filter on this pin prevents glitches from inadvertently activating this signal. Gate drive output: Connects to the gate of an external N-channel MOSFET. An internal clamp ensures that no more than 9V is applied between the GATE pin and the source of the external MOSFET. The GATE pin is immediately brought low when either the circuit breaker trips or an undervoltage lockout condition occurs. Circuit breaker sense input: A resistor between this pin and VCC sets the current-limit threshold. Whenever the voltage across the sense resistor exceeds the slow trip current-limit threshold (VTRIPSLOW), the GATE voltage is adjusted to ensure a constant load current. If VTRIPSLOW (50mV) is exceeded for longer than time period tOCSLOW, then the circuit breaker is tripped and the GATE pin is immediately pulled low. If the voltage across the sense resistor exceeds the fast trip circuit breaker threshold, VTRIPFAST, at any point due to fast, high amplitude power supply faults, then the GATE pin is immediately brought low without delay. To disable the circuit breaker, the SENSE and VCC pins can be tied together. The default VTRIPFAST for either device is 100mV. Other fast trip thresholds are available: 150mV, 200mV, or OFF (VTRIPFAST disabled). Please contact factory for availability of other options. Positive supply input: 2.3V to 13.2V. The GATE pin is held low by an internal undervoltage lockout circuit until VCC exceeds a threshold of 2.2V. If VCC exceeds 13.2V, an internal shunt regulator protects the chip from transient voltages up to 20V at the VCC and SENSE pins. PWRGD Power good output: Open-drain N-channel device, active high. When the voltage at the FB pin is lower than 1.24V, PWRGD output is held low. When the voltage at the FB pin exceeds 1.24V, then PWRGD is asserted immediately. The PWRGD pin requires a pull-up resistor (10k minimum) to VCC. CFILTER Current-limit response timer: A capacitor connected to this pin defines the period of time (tOCSLOW) in which an overcurrent event must last to signal a fault condition and trip the circuit breaker. If no capacitor is connected, then t OCSLOW defaults to 5s. /FAULT Circuit breaker fault status output: Open-drain N-channel device, active low. The /FAULT pin is asserted when the circuit breaker trips due to an overcurrent condition or when an undervoltage lockout condition exists. The/FAULT pin requires a pull-up resistor (10k minimum) to VCC. 3 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Pin Description (Continued) Pin Number 8-Pin SOIC Pin Number 16-Pin QSOP Pin Name n/a 13 DIS Discharge output: When the MIC2583/83R is turned off, a 500 internal resistor at this output allows the discharging of any load capacitance to ground. n/a 6, 9, 10 NC No internal connection. Pin Function Note: Please refer to the Applications Section and Figure 3 for a detailed explanation of the start-up and operation sequence of the MIC2582 pins shown in the Pin Description table. May 23, 2014 4 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Absolute Maximum Ratings(2) Operating Ratings(3) Supply Voltage (VCC) ..................................... -0.3V to +20V /POR, /FAULT, PWRGD Pins. ........................ -0.3V to 15V SENSE Pin ............................................-0.3V to VCC+0.3V ON Pin ...................................................-0.3V to VCC+0.3V GATE Pin ........................................................ -0.3V to 20V FB Input Pins ..................................................... -0.3V to 6V Junction Temperature .............................................. +125C Lead Temperature Standard Package (-JBM and -xBQS) (IR Reflow, Peak Temperature) ......... 240C + 0C/-5C Pb-Free Package (-xYM or -xYQS) (IR Reflow, Peak Temperature) ......... 260C + 0C/-5C (4) ESD Rating Human body model.................................................. 2kV Machine model ...................................................... 100V Supply Voltage (VCC) .................................. +2.3V to +13.2V Ambient Temperature (TA) .......................... -40C to +85C Junction Thermal Resistance SOIC (JA) ........................................................ 163C/W QSOP (JA) ...................................................... 112C/W Electrical Characteristics(5) VCC = 5.0V; TA = 25C, bold values indicate -40C TA +85C, unless noted. Symbol Parameter Condition Min. VCC Supply Voltage ICC Supply Current VON = 2V VTRIP Circuit Breaker Trip Voltage (Current-Limit Threshold) VTRIP = VCC - VSENSE External Gate Drive VTRIPSLOW IGATEOFF GATE Pin Pull-Up Current GATE Pin Sink Current ICPOR VTH VUV VUVHYS Units 13.2 V 1.5 2.5 mA 50 59 100 mV 85 130 175 100 150 200 110 170 225 mV mV mV 7 8 9 V 3.5 4.8 6.5 V Start Cycle, VGATE = 0V, VCC = 13.2V -30 17 -8 A VCC = 2.3V -26 17 -8 A VGATE - VCC VCC > 3V VGATE > 1V /FAULT = 0 (MIC2583/83R only) ITIMER 42 VTRIPFAST (MIC2582-Jxx) VCC = 2.3V IGATE Max. 2.3 VTRIPFAST (MIC2583/83R) X = J X=K X=L VGS Typ. VCC = 13.2V, Note 6 100 mA VCC = 2.3V, Note 6 50 mA Turn Off 110 A Current-Limit/Overcurrent Timer (CFILTER) Current (MIC2583/83R) VCC - VSENSE > VTRIPSLOW (timer on) -8.5 -6.5 -4.5 A VCC - VSENSE > VTRIPSLOW (timer off) 4.5 6.5 8.5 A Power-on-Reset Timer Current Timer on -3.5 2.5 -1.5 A Timer off 0.5 1.3 POR Delay and Overcurrent Timer (CFILTER) Threshold VCPOR rising VCFILTER rising (MIC2583/83R only) 1.19 1.245 1.30 V Undervoltage Lockout Threshold VCC rising 2.1 2.2 2.3 V VCC falling 1.90 2.05 2.20 V Undervoltage Lockout Hysteresis May 23, 2014 150 5 mA mV Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Electrical Characteristics(5) (Continued) Symbol Parameter Condition VON ON Pin Threshold Voltage 2.3V VCC 13.2V Min. Typ. Max. Units ON rising 1.19 1.24 1.29 V ON falling 1.14 1.19 1.24 V VONHYS ON Pin Hysteresis VON ON Pin Threshold Line Regulation 2.3V VCC 13.2V ION ON Pin Input Current VON = VCC VSTART Start-Up Delay Timer Threshold VCPOR rising 0.26 VAUTO Auto-Restart Threshold Voltage (MIC2583R only) Upper threshold IAUTO VFB 50 mV 2 mV -0.5 A 0.31 0.36 V 0.19 1.24 1.30 V Lower threshold 0.26 0.31 0.36 V Auto-Restart Current (MIC2583R only) Charge current 10 13 16 A 1.4 2 A Power-Good Threshold Voltage 2.3V = VCC = 13.2V VFBHYS FB Hysteresis IFBLKG FB Pin Leakage Current Discharge current FB rising 1.19 1.24 1.29 V FB falling 1.15 1.20 1.25 V 40 mV 2.3V = VCC = 13.2V, VFB = 1.3V 1.5 A IOUT = 1mA 0.4 V 1000 VOL /POR, /FAULT, PWRGD Output Voltage (/FAULT, PWRGD MIC2583/83R only) RDIS Output Discharge Resistance (MIC2583/83R only) tOCFAST Fast Overcurrent SENSE to GATE Low Trip Time VCC = 5V, VCC - VSENSE = 100mV CGATE = 10nF, Figure 1 1 s tOCSLOW Slow Overcurrent SENSE to GATE Low Trip Time VCC = 5V, VCC - VSENSE = 50mV CFILTER = 0, Figure 1 5 s tONDLY ON Delay Filter 20 s tFBDLY FB Delay Filter 20 s 500 Notes: 2. Exceeding the absolute maximum ratings may damage the device. 3. The device is not guaranteed to function outside its operating ratings. 4. Devices are ESD sensitive. Handling precautions are recommended. Human body model, 1.5k in series with 100pF. 5. Specification for packaged product only. 6. Not a tested parameter, guaranteed by design. May 23, 2014 6 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Timing Diagrams Figure 1. Current-Limit Response Figure 2. MIC2583 Power-on-Reset Response Figure 3. Power-on Start-up Delay Timing (7) Note: 7. Please refer to the Applications Section, Start-Up Cycle sub-section, for a detailed explanation of the timing shown in this figure. May 23, 2014 7 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Test Circuit Figure 4. Applications Test Circuit (not all pins shown for simplicity) May 23, 2014 8 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Typical Characteristics May 23, 2014 9 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Typical Characteristics (Continued) May 23, 2014 10 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Functional Characteristics May 23, 2014 11 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Functional Characteristics (Continued) May 23, 2014 12 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Functional Diagram May 23, 2014 13 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 and the voltage at the CPOR pin starts to rise. When the CPOR voltage reaches the threshold voltage (VTH, in Figure 3), the /POR pin goes high impedance, and is allowed to be pulled up by the external pull-up resistor on the /POR pin. This indicates that the output power is good. Functional Description Hot Swap Insertion When circuit boards are inserted into live system backplanes and supply voltages, high inrush currents can result due to the charging of bulk capacitance that resides across the supply pins of the circuit board. This inrush current, although transient in nature, may be high enough to cause permanent damage to on board components or may cause the system's supply voltages to go out of regulation during the transient period which may result in system failures. The MIC2582 and MIC2583 act as a controller for external N-channel MOSFET devices in which the gate drive is controlled to provide inrush current-limiting and output voltage slew rate control during hot plug insertions. In the MIC2583, when the FB threshold voltage (VFB) is reached, the power good (PWRGD) pin goes open circuit, high impedance, and is allowed to be pulled up by the external pull-up resistor on the PWRGD pin. The nondelayed power good feature is only available on the MIC2583. Active current regulation is employed to limit the inrush current transient response during start-up by regulating the load current at the programmed current-limit value (See the Current Limiting and Dual-Level Circuit Breaker section). The following equation is used to determine the nominal current-limit value: Power Supply VCC is the supply input to the MIC2582/83 controller with a voltage range of 2.3V to 13.2V. The VCC input can withstand transient spikes up to 20V. In order to ensure stability of the supply voltage, a minimum 0.47F capacitor from VCC to ground is recommended. Alternatively, a low pass filter, shown in the Typical Application circuit, can be used to eliminate high frequency oscillations as well as help suppress transient spikes. I LIM Start-Up Cycle Referring to Figure 3: When the VCC input voltage is first applied, it raises above the UVLO threshold voltage (VUV, in Figure 3). A minimum of 20s later, ( in Figure 3), the voltage on the ON pin can be taken above the ON pin threshold (VON). At that time the CPOR current source (ICPOR), is turned on, and the voltage at the CPOR pin starts to rise. See Table 2 for some typical supply start-up delays using several standard value capacitors. When the CPOR voltage reaches the start threshold voltage (VSTART, in Figure 3), two things happen: The external power FET driver charge pump is turned on, and the output voltage starts to rise. The capacitor on the CPOR pin is discharged to ground. INRUSH IGATE x CLOAD C 17A x LOAD CGATE CGATE Eq. 2 where IGATE is the GATE pin pull-up current, CLOAD is the load capacitance, and CGATE is the total GATE capacitance (CISS of the external MOSFET and any external capacitor connected from the MIC2582/83 GATE pin to ground). Load Capacitance-Dominated Start-Up In this case, the load capacitance (CLOAD) is large enough to cause the inrush current to exceed the programmed current limit but is less than the fast-trip threshold (or the fast-trip threshold is disabled, `M' option). During start-up under this condition, the load current is regulated at the programmed current-limit value (ILIM) and held constant The voltage on the feedback (FB) pin tracks the VOUT, output voltage through the feedback divider resistors (R1 and R2 in Figure 4). When the output voltage rises, and the FB voltage reaches the FB threshold voltage (V FB), the current source into the CPOR pin is again turned on, May 23, 2014 Eq. 1 where VTRIPSLOW is the current limit slow trip threshold found in the electrical table and RSENSE is the selected value that will set the desired current limit. There are two basic start-up modes for the MIC2582/83: Start-up dominated by load capacitance or Start-up dominated by total gate capacitance. The magnitude of the inrush current delivered to the load will determine the dominant mode. If the inrush current is greater than the programmed current limit (ILIM), then load capacitance is dominant. Otherwise, gate capacitance is dominant. The expected inrush current may be calculated using the following equation: Also, due to the existence of an undetermined amount of parasitic inductance in the absence of bulk capacitance along the supply path, placing a Zener diode at the VCC side of the controller to ground in order to provide external supply transient protection is strongly recommended for relatively high current applications (3A). See the Typical Application. VTRIPSLOW 50mV RSENSE RSENSE 14 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Table 1. Output Slew Rate Selection for Gate CapacitanceDominated Start-Up until the output voltage rises to its final value. The output slew rate and equivalent GATE voltage slew rate is computed by the following equation: Output voltage slew rate: dVOUT/dt = I LIM C LOAD IGATE = 17A Eq. 3 where ILIM is the programmed current-limit value. Consequently, the value of CFILTER must be selected to ensure that the overcurrent response time, tOCSLOW, exceeds the time needed for the output to reach its final value. For example, given a MOSFET with an input capacitance CISS = CGATE = 4700pF, CLOAD is 2200F, and ILIM is set to 6A with a 12V input, then the load capacitance dominates as determined by the calculated 6A V 2.73 2200F ms Eq. 4 and the resulting tOCSLOW needed to achieve a 12V output is approximately 4.5ms. (See Power-on-Reset and Overcurrent Timer Delays section to calculate tOCSLOW ). GATE Capacitance-Dominated Start-Up In this case, the value of the load capacitance relative to the GATE capacitance is small enough such that the load current during start-up never exceeds the current-limit threshold as determined by Equation 1. The minimum value of CGATE that will ensure that the current limit is never exceeded is given by the equation below: dVOUT/dt = IGATE CGATE dVOUT/dt 0.001F 17V/ms 0.01F 1.7V/ms 0.1F 0.17V/ms 1F 0.017V/ms Current Limiting and Dual-Level Circuit Breaking Many applications will require that the inrush and steady state supply current be limited at a specific value in order to protect critical components within the system. Connecting a sense resistor between the VCC and SENSE pins sets the nominal current limit value of the MIC2582/83 and the current limit is calculated using Equation 1. INRUSH > ILIM. Therefore, the output voltage slew rate determined from Equation 3 is: Output voltage slew rate: dVOUT/dt = CGATE Eq. 5 The MIC2582/83 also features a dual-level circuit breaker triggered via the 50mV and 100mV current-limit thresholds which are sensed across the VCC and SENSE pins. The first level of the circuit breaker functions as follows. For the MIC2583/83R, once the voltage sensed across these two pins exceeds 50mV, the overcurrent timer, its duration set by capacitor CFILTER, starts to ramp the voltage at CFILTER using a 6.5A constant current source. If the voltage at CFILTER reaches the overcurrent timer threshold (VTH) of 1.24V, then CFILTER immediately returns to ground as the circuit breaker trips and the GATE output is immediately shut down. The default overcurrent time period for the MIC2582/83 is 5s. For the second level, if the voltage sensed across VCC and SENSE exceeds 100mV at any time, the circuit breaker trips and the GATE shuts down immediately, bypassing the overcurrent time period. The MIC2582-MYM option is equipped with only a single circuit breaker threshold (50mV). To disable current-limit and circuit breaker operation, tie the SENSE and VCC pins together and the CFILTER (MIC2583/83R) pin to ground. Output Undervoltage Detection The MIC2582/83 employ output undervoltage detection by monitoring the output voltage through a resistive divider connected at the FB pin. During turn-on, while the voltage at the FB pin is below the threshold (VFB), the /POR pin is asserted low. Table 1 depicts the output slew rate for various values of CGATE. Once the FB pin voltage crosses VFB, a 2.5A current source charges capacitor CPOR. Once the CPOR pin voltage reaches 1.24V, the time period tPOR elapses as the CPOR pin is pulled to ground and the /POR pin goes HIGH. If the voltage at FB drops below VFB for more than 10s, the /POR pin resets for at least one timing cycle May 23, 2014 15 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Table 2. Selected Power-on-Reset and Start-Up Delays defined by tPOR (See Applications Information for an example). Power-on-Reset and Overcurrent Timer Delays The Power-on-Reset delay, tPOR, is the time period for the /POR pin to go HIGH once the voltage at the FB pin exceeds the power good threshold (VFB). A capacitor connected to CPOR sets the interval and is determined by using Equation 6: t POR CPOR VTH 0.5 CPOR F ICPOR Eq. 6 tSTART tPOR 0.01F 1.2ms 5ms 0.02F 2.4ms 10ms 0.033F 4ms 16.5ms 0.05F 6ms 25ms 0.1F 12ms 50ms 0.33F 40ms 165ms 0.47F 56ms 235ms 1F 120ms 500ms Table 3. Selected Overcurrent Timer Delays where the Power-on-Reset threshold (VTH) and timer current (ICPOR) are typically 1.24V and 2.5A, respectively. For the MIC2583/83R, a capacitor connected to CFILTER is used to set the timer which activates the circuit breaker during overcurrent conditions. When the voltage across the sense resistor exceeds the slow trip current-limit threshold of 50mV, the overcurrent timer begins to charge for a time period (tOCSLOW), determined by CFILTER. When no capacitor is connected to CFILTER and for the MIC2582, tOCSLOW defaults to 5s. If tOCSLOW elapses, then the circuit breaker is activated and the GATE output is immediately pulled to ground. For the MIC2583/83R, the following equation is used to determine the overcurrent timer period, tOCSLOW . t OCSLOW CFILTER CPOR CFILTER tOCSLOW 680pF 130s 2200pF 420s 4700pF 900s 8200pF 1.5ms 0.033F 6ms 0.1F 19ms 0.22F 42ms 0.47F 90ms VTH 0.19 CFILTER ( F ) Eq. 7 ITIMER where VTH, the CFILTER timer threshold, is 1.24V and ITIMER, the overcurrent timer current, is 6.5A. Table 2 and Table 3 provide a quick reference for several timer calculations using select standard value capacitors. May 23, 2014 16 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 VOUT(Good) R5 R 6 VFB(MAX) Application Information Design Consideration for Output Undervoltage Detection For output undervoltage detection, the first consideration is to establish the output voltage level that indicates "power is good." For this example, the output value for which a 12V supply will signal "good" is 11V. Next, consider the tolerances of the input supply and FB threshold (VFB). For this example, the 12V supply varies 5%, thus the resulting output voltage may be as low as 11.4V and as high as 12.6V. Additionally, the FB threshold has 50mV tolerance and may be as low as 1.19V and as high as 1.29V. Thus, to determine the values of the resistive divider network (R5 and R6) at the FB pin, shown in the typical application circuit on page 1, use the following iterative design procedure. VFB(MAX) 100A 1.29V 12.9k 100A Now, consider the 11.4V minimum output voltage, the lower tolerance for R6 and higher tolerance for R5, 12.28k and 94.03k, respectively. With only 11.4V available, the voltage sensed at the FB pin exceeds VFB(MAX), thus the /POR and PWRGD (MIC2583/83R) signals will transition from LOW to HIGH, indicating "power is good" given the worse case tolerances of this example. Lastly, in giving consideration to the leakage current associated with the FB input, it is recommended to either provide ample design margin (20mV to 30mV) to allow for loss in the potential (V) at the FB pin, or allow >100A to flow in the FB resistor network. PCB Connection Sense There are several configuration options for the MIC2582/83's ON pin to detect if the PCB has been fully seated in the backplane before initiating a start-up cycle. In the typical applications circuit, the MIC2582/83 is mounted on the PCB with a resistive divider network connected to the ON pin. R2 is connected to a short pin on the PCB edge connector. Until the connectors mate, the ON pin is held low which keeps the GATE output charge pump off. Once the connectors mate, the resistor network is pulled up to the input supply, Eq. 8 R6 is chosen as 12.4k 1% Next, determine R5 using the output "good" voltage of 11V and the following equation. R5 R6 VOUT(Good) VFB R6 Eq. 10 where VFB(MAX) = 1.29V, VOUT(Good) = 11V, and R6 is 12.4k. Substituting these values into Equation 10 now yields R5 = 93.33k. A standard 93.1k 1% is selected. Choose R6 to allow 100A or more in the FB resistive divider branch. R6 1 Eq. 9 Using some basic algebra and simplifying Equation 9 to isolate R5 yields: Figure 5. PCB Connection Sense with ON/OFF Control May 23, 2014 17 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 5V Switch with 3.3V Supply Generation The MIC2582/83 can be configured to switch a primary supply while generating a secondary regulated voltage rail. The circuit in Figure 8 enables the MIC2582 to switch a 5V supply while also providing a 3.3V low dropout regulated supply with only a few added external components. Upon enabling the MIC2582, the GATE output voltage increases and thus the 3.3V supply also begins to ramp. As the 3.3V output supply crosses 3.3V, the FB pin threshold is also exceeded which triggers the power-on reset comparator. The /POR pin goes HIGH, turning on transistor Q3 which lowers the voltage on the gate of MOSFET Q2. The result is a regulated 3.3V supply with the gate feedback loop of Q2 compensated by capacitor C3 and resistors R4 and R5. For MOSFET Q2, special consideration must be given to the power dissipation capability of the selected MOSFET as 1.5V to 2V will drop across the device during normal operation in this application. Therefore, the device is susceptible to overheating dependent upon the current requirements for the regulated output. In this example, the power dissipated by Q2 is approximately 1W. However, a substantial amount of power will be generated with higher current requirements and/or conditions. As a general guideline, expect the ambient temperature within the power supply box to exceed the maximum operating ambient temperature of the system environment by approximately 20C. Given the MOSFET's R(JA) and the expected power dissipated by the MOSFET, an approximation for the junction temperature at which the device will operate is obtained as follows: 12V in this example, and the ON pin voltage exceeds its threshold (VON) of 1.24V and the MIC2582/83 initiates a start-up cycle. In Figure 5, the connection sense consisting of a discrete logic-level MOSFET and a few resistors allows for interrupt control from the processor or other signal controller to shut off the output of the MIC2582/83. R4 pulls the GATE of Q2 to VIN and the ON pin is held low until the connectors are fully mated. Once the connectors fully mate, a logic LOW at the /ON_OFF signal turns Q2 off and allows the ON pin to pull up above its threshold and initiate a start-up cycle. Applying a logic HIGH at the /ON_OFF signal will turn Q2 on and short the ON pin of the MIC2582/83 to ground which turns off the GATE output charge pump. Higher UVLO Setting Once a PCB is inserted into a backplane (power supply), the internal UVLO circuit of the MIC2582/83 holds the GATE output charge pump off until VCC exceeds 2.2V. If VCC falls below 2.1V, the UVLO circuit pulls the GATE output to ground and clears the overvoltage and/or current limit faults. A typical 12V application, for example, should implement a higher UVLO than the internal 2.1V threshold of MIC2582 to avoid delivering power to downstream modules/loads while the input is below tolerance. For a higher UVLO threshold, the circuit in Figure 6 can be used to delay the output MOSFET from switching on until the desired input voltage is achieved. The circuit allows the charge pump to remain off until VIN exceeds R1 1 1.24V . The GATE drive output will be shut R2 R1 down when VIN falls below 1 1.19V . In the R2 example circuit (Figure 6), the rising UVLO threshold is set at approximately 9.5V and the falling UVLO threshold is established as 9.1V. The circuit consists of an external resistor divider at the ON pin that keeps the GATE output charge pump off until the voltage at the ON pin exceeds its threshold (VON) and after the start-up timer elapses. TJ = (PD x R(JA)) + TA Eq. 11 where TA = TA(MAX OPERATING) + 20C. As a precaution, the implementation of additional copper heat sinking is highly recommended for the area under/around the MOSFET Figure 6. Higher UVLO Setting May 23, 2014 18 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 For additional information on MOSFET thermal considerations, please see MOSFET Selection text and subsequent sections. Once the value of RSENSE has been chosen in this manner, it is good practice to check the maximum ILOAD(CONT) which the circuit may let through in the case of tolerance buildup in the opposite direction. Here, the worst-case maximum current is found using a 59mV trip voltage and a sense resistor that is 3% low in value. The resulting equation is: Auto-Restart for MIC2583R The MIC2583R provides an auto-restart function. Upon an overcurrent fault condition such as a short circuit, the MIC2583R initially shuts off the GATE output. The MIC2583R attempts to restart with a 12A charge current at a preset 10% duty cycle until the fault condition is removed. The interval between auto-retry attempts is set by capacitor CFILTER. I LOAD (CONT ,MAX ) 42mV As an example, if an output must carry a continuous 2A without nuisance trips occurring, Equation 12 yields: RSENSE (MAX ) 40.8mV 20.4m. 2A The next lowest standard value is 20m. At the other set of tolerance extremes for the output in question, The current limit threshold voltage (i.e., the "trip point") for the MIC2582/83 may be as low as 42mV, which would equate to a sense resistor value of 42mV/ILOAD(CONT). Carrying the numbers through for the case where the value of the sense resistor is 3% high yields: 1.03I LOAD(CONT ) Eq. 13 Sense Resistor Selection The MIC2582 and MIC2583 use a low-value sense resistor to measure the current flowing through the MOSFET switch (and therefore the load). This sense resistor is nominally set at 50mV/ILOAD(CONT). To accommodate worstcase tolerances for both the sense resistor (allow 3% over time and temperature for a resistor with 1% initial tolerance) and still supply the maximum required steadystate load current, a slightly more detailed calculation must be used. RSENSE(MAX ) 59mV 60.8mV (0.97) RSENSE (NOM ) RSENSE (NOM ) I LOAD (CONT ,MAX ) 40.8mV I LOAD(CONT ) 60.8mV 3.04A 20.0m approximately 3A. Knowing this final data, we can determine the necessary wattage of the sense resistor 2 using P = I R, where I will be ILOAD(CONT, MAX), and R will be (0.97)(RSENSE(NOM)). These numbers yield the following: 2 PMAX = (3A) (19.4m) = 0.175W. Eq. 12 In this example, a 1/4W sense resistor is sufficient. Figure 7. 5V Switch/3.3V LDO Application May 23, 2014 19 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 At the same time, if the output of the external MOSFET (its source) is suddenly subjected to a short, the gate-source voltage will go to (19.5V - 0V) = 19.5V. This means that the external MOSFET must be chosen to have a gatesource breakdown voltage of 20V or more, which is an available standard maximum value. However, if operation is at or above 13V, the 20V gate-source maximum will likely be exceeded. As a result, an external Zener diode clamp should be used to prevent breakdown of the external MOSFET when operating at voltages above 8V. A Zener diode with 10V rating is recommended as shown in Figure 8. At the present time, most power MOSFETs with a 20V gate-source voltage rating have a 30V drain-source breakdown rating or higher. MOSFET Selection Selecting the proper external MOSFET for use with the MIC2582/83 involves three straightforward tasks. The choice of a MOSFET that meets minimum voltage requirements. The selection of a device to handle the maximum continuous current (steady-state thermal issues). Verification of the selected part's ability to withstand any peak currents (transient thermal issues). MOSFET Voltage Requirements The first voltage requirement for the MOSFET is easily stated: the drain-source breakdown voltage of the MOSFET must be greater than VIN(MAX). For instance, a 12V input may reasonably be expected to see highfrequency transients as high as 18V. Therefore, the drainsource breakdown voltage of the MOSFET must be at least 19V. For ample safety margin and standard availability, the closest value will be 20V. As a general tip, choose surface-mount devices with a drain-source rating of 30V as a starting point. Finally, the external gate drive of the MIC2582/83 requires a low-voltage logic level MOSFET when operating at voltages lower than 3V. There are 2.5V logic level MOSFETs available. Please see Table 4 "MOSFET and Sense Resistor Vendors" for suggested manufacturers. The second breakdown voltage criterion that must be met is a bit subtler than simple drain-source breakdown voltage, but is not hard to meet. In MIC2582/83 applications, the gate of the external MOSFET is driven up to approximately 19.5V by the internal output MOSFET (again, assuming 12V operation). Figure 8. Zener-Clamped MOSFET Gate May 23, 2014 20 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 MOSFET Steady-State Thermal Issues The selection of a MOSFET to meet the maximum continuous current is a fairly straightforward exercise. First, the designer needs the following data: The value of ILOAD(CONT, MAX.) for the output in question (see Sense Resistor Selection). The manufacturer's datasheet for the candidate MOSFET. The maximum ambient temperature in which the device will be required to operate. Any knowledge one can get about the heat sinking available to the device (e.g., can heat be dissipated into the ground plane or power plane, if using a surface-mount part? Is any airflow available?). can, position the MOSFET(s) near the inlet of a power supply's fan, or the outlet of a processor's cooling fan. MOSFET Transient Thermal Issues Having chosen a MOSFET that will withstand the imposed 2 voltage stresses, and the worse case continuous I R power dissipation which it will see, it remains only to verify the MOSFETs ability to handle short-term overload power dissipation without overheating. A MOSFET can handle a much higher pulsed power without damage than its continuous dissipation ratings would imply. The reason for this is that, like everything else, thermal devices (silicon die, lead frames, etc.) have thermal inertia. The datasheet will almost always give a value of on resistance given for the MOSFET at a gate-source voltage of 4.5V, and another value at a gate-source voltage of 10V. As a first approximation, add the two values together and divide by two to get the on-resistance of the part with 8V of enhancement. In terms related directly to the specification and use of power MOSFETs, this is known as "transient thermal impedance," or Z(JA). Almost all power MOSFET datasheets give a Transient Thermal Impedance Curve. For example, take the following case: VIN = 12V, tOCSLOW has been set to 100ms, ILOAD(CONT. MAX) is 2.5A, the slow-trip threshold is 50mV nominal, and the fast-trip threshold is 100mV. If the output is accidentally connected to a 3 load, the output current from the MOSFET will be regulated to 2.5A for 100ms (tOCSLOW) before the part trips. During that time, the dissipation in the MOSFET is given by: Call this value RON. Since a heavily enhanced MOSFET acts as an ohmic (resistive) device, almost all that's required to determine steady-state power dissipation is to 2 calculate I R. The one addendum to this is that MOSFETs have a slight increase in RON with increasing die temperature. A good approximation for this value is 0.5% increase in R ON per C rise in junction temperature above the point at which RON was initially specified by the manufacturer. For instance, if the selected MOSFET has a calculated RON of 10m at a TJ = 25C, and the actual junction temperature ends up at 110C, a good first cut at the operating value for RON would be: P = E x I; EMOSFET = [12V-(2.5A)(3)] = 4.5V PMOSFET = (4.5V x 2.5A) = 11.25W for 100ms. At first glance, it would appear that a really hefty MOSFET is required to withstand this sort of fault condition. This is where the transient thermal impedance curves become very useful. Figure 9 shows the curve for the Vishay (Siliconix) Si4410DY, a commonly used SOIC-8 power MOSFET. RON 10m 1 110 250.005 14.3m Eq. 14 The final step is to make sure that the heat sinking available to the MOSFET is capable of dissipating at least as much power (rated in C/W) as that with which the MOSFETs performance was specified by the manufacturer. Here are a few practical tips: The heat from a surface-mount device such as an SOIC-8 MOSFET flows almost entirely out of the drain leads. If the drain leads can be soldered down to one square inch or more, the copper will act as the heat sink for the part. This copper must be on the same layer of the board as the MOSFET drain. Airflow works. Even a few LFM (linear feet per minute) of air will cool a MOSFET down substantially. If you May 23, 2014 The best test of a surface-mount MOSFET for an application (assuming the above tips show it to be a likely fit) is an empirical one. Check the MOSFETs temperature in the actual layout of the expected final circuit, at full operating current. The use of a thermocouple on the drain leads, or infrared pyrometer on the package, will then give a reasonable idea of the device's junction temperature. Taking the simplest case first, we'll assume that once a fault event such as the one in question occurs, it will be a long time-ten minutes or more-before the fault is isolated and the channel is reset. In such a case, we can approximate this as a "single pulse" event, that is to say, there's no significant duty cycle. Then, reading up from the X-axis at the point where "Square Wave Pulse Duration" is equal to 0.1sec (=100ms), we see that the Z(JA) of this MOSFET to a highly infrequent event of this duration is only 8% of its continuous R(JA). This particular part is specified as having an R(JA) of 50C/W for intervals of 10 seconds or less. 21 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 TJ 55C + [17m + (55C-25C)(0.005)(17m)] Thus: 2 Assume TA = 55C maximum, 1 square inch of copper at the drain leads, no airflow. x (2.5A) x (50C/W) TJ (55C + (0.122W)(50C/W) Recalling from our previous approximation hint, the part has an RON of (0.0335/2) = 17m at 25C. TJ 61.1C Iterate the calculation once to see if this value is within a few percent of the expected final value. For this iteration we will start with TJ equal to the already calculated value of 61.1C: Assume it has been carrying just about 2.5A for some time. When performing this calculation, be sure to use the highest anticipated ambient temperature (T A(MAX)) in which the MOSFET will be operating as the starting temperature, and find the operating junction temperature increase (T J) from that point. Then, as shown next, the final junction temperature is found by adding T A(MAX) and TJ. Since this is not a closed-form equation, getting a close approximation may take one or two iterations, and the calculation tends to converge quickly. TJ TA + [17m + (61.1C-25C)(0.005)(17m)] 2 x (2.5A) x (50C/W) TJ (55C + (0.125W)(50C/W) 61.27C So our original approximation of 61.1C was very close to the correct value. We will use TJ = 61C. Finally, add the temperature increase due to the maximum power dissipation calculated from a "single event", (11.25W)(50C/W)(0.08) = 45C to the steady-state TJ to get TJ(TRANSIENT MAX.) = 106C. This is an acceptable maximum junction temperature for this part. Then the starting (steady-state) TJ is: TJ TA(MAX) + TJ TJ TA(MAX) + [RON + TA(MAX) - TA)(0.005/C)(RON)] 2 x I x R(JA) Figure 9. Transient Thermal Impedance May 23, 2014 22 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 PCB Layout Considerations Because of the low values of the sense resistors used with the MIC2582/83 controllers, special attention to the layout must be used in order for the device's circuit breaker function to operate properly. Specifically, the use of a 4wire Kelvin connection to accurately measure the voltage across RSENSE is highly recommended. Kelvin sensing is simply a means of making sure that any voltage drops in the power traces connecting to the resistors does not get picked up by the traces themselves. Additionally, these Kelvin connections should be isolated from all other signal traces to avoid introducing noise onto these sensitive nodes. Figure 10 illustrates a recommended, single layer layout for the RSENSE, power MOSFET, timer(s), and feedback network connections. The feedback network resistor values are selected for a 12V application. Many hot swap applications will require load currents of several amperes. Therefore, the power (VCC and Return) trace widths (W) need to be wide enough to allow the current to flow while the rise in temperature for a given copper plate (e.g., 1oz. or 2oz.) is kept to a maximum of 10C~25C. Also, these traces should be as short as possible in order to minimize the IR drops between the input and the load. Finally, the use of plated-through vias will be needed to make circuit connections to power and ground planes when utilizing multi-layer PC boards. MOSFET and Sense Resistor Vendors Device types and manufacturer contact information for power MOSFETs and sense resistors are provided in Table 4. Some of the recommended MOSFETs include a metal heat sink on the bottom side of the package. The recommended trace for the MOSFET Gate of Figure 10 must be redirected when using MOSFETs packaged in this style. Contact the device manufacturer for package information. Figure 10. Recommended PCB Layout for Sense Resistor, Power MOSFET, and Feedback Network May 23, 2014 23 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Table 4. MOSFET and Sense Resistor Vendors (8) MOSFET Vendor Key MOSFET Type(s) Applications Contact Information Vishay (Siliconix) Si4420DY (SOIC-8) package Si4442DY (SOIC-8) package Si4876DY (SOIC-8) package (R) Si7892DY (PowerPAK SOIC-8) IOUT 10A IOUT = 10-15A, VCC < 3V IOUT 5A, VCC 5V IOUT 15A www.siliconix.com (203) 452-5664 International Rectifier IRF7413 (SOIC-8) package IRF7457 (SOIC-8) package IRF7601 (SOIC-8) package IOUT 10A IOUT = 10-15A IOUT 5A, VCC < 3V www.irf.com (310) 322-3331 Fairchild Semiconductor FDS6680A (SOIC-8) package IOUT 10A www.fairchildsemi.com (207) 775-8100 Philips PH3230 (SOT669-LFPAK) IOUT 20A www.philips.com Hitachi HAT2099H (LFPAK) IOUT 20A www.halsp.hitachi.com (408) 433-1990 Note: 8. These devices are not limited to these conditions in many cases, but these conditions are provided as a helpful reference for customer applications. Resistor Vendors Sense Resistors Contact Information Vishay (Dale) "WSL" Series www.vishay.com/docswsl_30100.pdf (203) 452-5664 IRC "OARS" Series "LR" Series (second source to "WSL") www.irctt.com/pdf_files/OARS.pdf www.irctt.com/pdf_files/LRC.pdf (828) 264-8861 May 23, 2014 24 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Package Information(9) 8-Pin SOIC (M) May 23, 2014 25 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 Package Information(9) (Continued) 16-Pin QSOP (QS) Note: 9. Package information is correct as of the publication date. For updates and most current information, go to www.micrel.com. May 23, 2014 26 Revision 5.0 Micrel, Inc. MIC2582/MIC5283 MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http://www.micrel.com Micrel makes no representations or warranties with respect to the accuracy or completeness of the information furnished in this data sheet. This information is not intended as a warranty and Micrel does not assume responsibility for its use. Micrel reserves the right to change circuitry, specifications and descriptions at any time without notice. No license, whether express, implied, arising by estoppel or otherwise, to any intellectual property rights is granted by this document. Except as provided in Micrel's terms and conditions of sale for such products, Micrel assumes no liability whatsoever, and Micrel disclaims any express or implied warranty relating to the sale and/or use of Micrel products including liability or warranties relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right. Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser's use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser's own risk and Purchaser agrees to fully indemnify Micrel for any damages resulting from such use or sale. (c) 2014 Micrel, Incorporated. May 23, 2014 27 Revision 5.0 Mouser Electronics Authorized Distributor Click to View Pricing, Inventory, Delivery & Lifecycle Information: Micrel: MIC2582-JYM MIC2582-JYM TR MIC2582-MYM MIC2582-MYM TR MIC2583-JYQS MIC2583-JYQS TR MIC2583-KYQS MIC2583-KYQS TR MIC2583-LYQS MIC2583-LYQS TR MIC2583-MYQS MIC2583-MYQS TR MIC2583R-JYQS MIC2583R-JYQS TR MIC2583R-KYQS MIC2583R-KYQS TR MIC2583R-LYQS MIC2583R-LYQS TR MIC2583R-MYQS MIC2583R-MYQS TR MIC2583-MYQS-TR MIC2583R-JYQS-TR MIC2582-MYM-TR MIC2583-KYQS-TR MIC2583-LYQS-TR MIC2583-JYQS-TR MIC2583R-MYQS-TR MIC2583R-KYQS-TR MIC2582JYM-TR MIC2583R-LYQS-TR