HIP1020 ® Data Sheet July 2004 FN4601.2 Single, Double or Triple-Output Hot Plug Controller Features The HIP1020 applies a linear voltage ramp to the gates of any combination of 3.3V, 5V, and 12V MOSFETs. The internal charge pump doubles a 12V bias or triples a 5V bias to deliver the high-side drive capability required when using more cost-effective N-Channel MOSFETs. The 5V/ms ramp rate is controlled internally and is the proper value to turn on most devices within the Device-Bay-specified di/dt limit. If a slower rate is required, the internally-determined ramp rate can be over ridden using an optional external capacitor. • No Additional Components Required When VCC = 12V, the charge pump ramps the voltage on HGATE from zero to 22V in about 4ms. This allows either a standard or a logic-level MOSFET to become fully enhanced when used as a high-side switch for 12V power control. The voltage on LGATE ramps from zero to 16V allowing the simultaneous control of 3.3V and/or 5V MOSFETs. • Rise Time Controlled to Device-Bay Specifications • Internal Charge Pump Drives N-Channel MOSFETs • Drives any Combination of One, Two or Three Outputs • Internally-Controlled Turn-On Ramp - Optional Capacitor Selects Slower Rates • Prevents False Turn on During Hot Insertion • Operates using 12V or 5V Bias • Improves Device Bay Peripheral Size Cost and Complexity - Minimal Component Count - Tiny 5-Pin SOT23 Package • Controls Standard and Logic-Level MOSFETs • Compatible with TTL and 3.3V Logic Devices • Shutdown Current . . . . . . . . . . . . . . . . . . . . . . . . . . < 1µA When VCC = 5V, the charge pump enters voltage-tripler mode. The voltage on HGATE ramps from zero to 12.5V in about 3ms while LGATE ramps to 12.0V. This mode is ideal for control of high-side MOSFET switches used in 3.3V and 5V power switching when 12V bias is not available. • Operating Current . . . . . . . . . . . . . . . . . . . . . . . . . .< 3mA Ordering Information • Power Distribution Control PART NUMBER TEMP. RANGE (oC) PKG. DWG. # PACKAGE HIP1020CK-T 0 to 70 5 Ld SOT23 T + R P5.064 HIP1020CKZ-T (See Note) 0 to 70 5 Ld SOT23 T + R (Pb-free) Applications • Device Bay Peripherals • Hot Plug Control Pinout HIP1020 (SOT23) TOP VIEW P5.064 NOTE: Intersil Pb-free products employ special Pb-free material sets; molding compounds/die attach materials and 100% matte tin plate termination finish, which is compatible with both SnPb and Pb-free soldering operations. Intersil Pb-free products are MSL classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J Std-020B. VCC 1 GND 2 LGATE 3 5 EN 4 HGATE Typical Applications ENABLE HIP1020 ENABLE HIP1020 1 CHARGE PUMP 5 OPTIONAL 1 C1 2 CHARGE PUMP 5 C1 2 3 OPTIONAL 4 3 V12 4 V12,OUT V5 V5,OUT V33 V33,OUT FIGURE 1A. DEVICE-BAY HOT PLUG CONTROLLER WITH VCC = 12V 1 V5 V5,OUT V33 V33,OUT FIGURE 1B. DEVICE-BAY HOT PLUG CONTROLLER WITH VCC = 5V CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures. 1-888-INTERSIL or 321-724-7143 | Intersil (and design) is a registered trademark of Intersil Americas Inc. Copyright © Intersil Americas Inc. 1999, 2004. All Rights Reserved All other trademarks mentioned are the property of their respective owners. HIP1020 Pin Descriptions PIN SYMBOL FUNCTION 1 VCC Bias Supply Connect this pin to either a 12V or a 5V source. The HIP1020 detects the bias-voltage level at pin 1 and decides whether to operate as a voltage-doubler or a voltage-tripler. Consequently, it is not recommended to operate with bias voltages between 5V (±10%) and 12V (±10%). In the absence of an enable signal at pin 5, the current into pin 1 is less than 1µA. It is necessary for voltage to be present at pin 1 prior to applying an enable signal at pin 5. 2 GND Ground Connect to the negative rail of the supply that is connected to pin 1. 3 LGATE Gate Driver for the 5V When VCC = 12V, connect this pin to the gate(s) of the 5V and/or 3.3V MOSFETs. When VCC and/or 3.3V = 5V, connect this pin to the gate of a 3.3V MOSFET. Upon a rising edge on EN (pin 5), the voltage on this pin will ramp linearly to ~16V when VCC = 12V and ~12V when VCC = 5V. An MOSFET(s) internal dv/dt activated clamp shunts coupled noise to ground preventing unintended turn on at either output. The internal dv/dt-activated clamp also protects pin 5. 4 HGATE 12V or 5V MOSFET Gate Driver When VCC = 12V, connect this pin to the gate of the 12V MOSFET. When VCC = 5V, connect this pin to the gate of the 5V MOSFET. Upon a rising edge on EN (pin 5), the voltage on this pin will ramp linearly to ~22V when VCC = 12V and ~13V when VCC = 5V. 5 EN Enable Connect a TTL or 3.3V logic signal to this pin to control the outputs at pins 3 and 4. A rising edge on pin 5 initiates the linear voltage ramps at pins 3 and 4. Be sure that the device driving EN does not enter a high-impedance state when enabling is not desired and that it’s maximum rise time does not exceed 100µs. 2 DESCRIPTION HIP1020 Absolute Maximum Ratings Thermal Information Supply Voltage, VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.5V HGATE Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10mA LGATE Current. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10mA EN Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.0V Thermal Resistance (Typical, Note 1) θJA (oC/W) SOT23/5L Package . . . . . . . . . . . . . . . . . . . . . . . . . 240 Maximum Junction Temperature . . . . . . . . . . . . . . . . . . . . . . .150oC Maximum Storage Temperature Range . . . . . . . . . . -65oC to 150oC Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . .300oC Operating Conditions Supply Voltage, VCC . . . . . . . . . . . . . . . . . . .5V ±10% or 12V ±10% Temperature Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0oC to 70oC CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. NOTE: 1. θJA is measured with the component mounted on an evaluation PC board in free air. Electrical Specifications PARAMETER SYMBOL TEST CONDITIONS MIN TYP MAX UNITS VCC SUPPLY CURRENT Operating Supply ICC,12 VEN = 5V,VCC = 12V - 1.6 2.3 mA Operating Supply ICC,5 VEN = 5V, VCC = 5V - 0.77 1.1 mA Shutdown Supply ISHDN VEN = 0V - - 1 µA VCC = 12V 2.5 5 8.5 V/ms VCC = 5V 2.4 5 7.2 V/ms VCC = 12V 2.5 5 8.5 V/ms VCC = 5V 2.6 5 7.4 V/ms VCC = 12V, VHGATE = 19V 7.6 13.4 18.5 µA VCC = 5V, VHGATE = 9.5V 7.6 12.3 18.5 µA VCC = 12V 20.7 21.8 22.8 V VCC = 5V 11.6 12.5 13.4 V VCC = 12V 15.2 16.3 18.3 V VCC = 5V 10.6 11.7 12.9 V GATE CONTROL OUTPUTS HGATE dv/dt (No External Capacitor) LGATE dv/dt (No External Capacitor) HGATE Pull-Up Current dv/dt dv/dt IHGATE HGATE Output Voltage VHGATE LGATE Output Voltage VLGATE ENABLE Input Threshold Voltage VEN VCC = 12V 1 - 2.4 V Enable Current IEN VEN = 5V - - 1 µA 3 HIP1020 Typical Performance Curves 25 25 NOTE 2 20 20 NOTE 3 15 NOTE 2 15 10 VOLTS VOLTS NOTE 3 C1 = 10nF C122nF = 22nF 10 C1 = 22nF 5 5 0 0 -5 C1 = 10nF -5 0 10 20 30 40 0 50 10 MILLISECONDS 20 30 40 50 MILLISECONDS FIGURE 2. HGATE (PIN 4) TURNING ON WITH VCC = 12V FIGURE 3. LGATE (PIN 3) TURNING ON WITH VCC = 12V 15 15 NOTE 3 NOTE 2 NOTE 2 NOTE 3 C1 = 10nF 10 C1 = 10nF 10 VOLTS VOLTS C1 = 22nF 5 0 C1 = 22nF 5 0 -5 -5 0 10 20 30 40 50 0 10 30 40 50 MILLISECONDS MILLISECONDS FIGURE 4. HGATE (PIN 4) TURNING ON WITH VCC = 5V 20 FIGURE 5. LGATE (PIN 3)TURNING ON WITH VCC = 5V NOTES: Device is enabled at 10 milliseconds. 2. Pins 3 and 4 are unconnected. 3. Pins 3 and 4 are connected to the gates of “typical” high-performance N-Channel MOSFETs. Application Information The HIP1020 was designed specifically to address the requirements of Device Bay peripherals. The small package, low cost and integrated features make it the ideal component for high-side power control of all three Device-Bay rail voltages without using any additional components except for the switching MOSFETs themselves. The integrated charge pump supplies sufficient voltage to fully enhance the lowercost N-Channel power MOSFETs, and the internallycontrolled turn-on ramp provides soft switching for all types of loads. Although the HIP1020 was developed with Device Bay in mind, it has the versatility to perform in any situation where low-cost load switching is required. 4 MOSFET Selection for Device Bay Peripherals When selecting power MOSFETs for Device Bay (or any similar application), two major concerns are the voltage drop across the MOSFET and the thermal requirements imposed by the particular application. Voltage drop across the MOSFET is controlled by its on-state resistance, rDS(ON), and the peak current through the device, while the thermal requirements are determined by several factors including ambient temperature, amount of air flow if any, area of the copper mounting pad, the thermal characteristics of the MOSFET and its package, and the average current through the MOSFET. HIP1020 TABLE 1. DEVICE-BAY MOSFET SELECTION GUIDE FOR PERIPHERAL-POWER CONTROL INTERSIL PART NO. MOUNTING-PAD AREA (IN2) HUF76105DK8 0.05 HUF76113DK8 PACKAGE SO-8 0.05 SO-8 rDS(ON) (mΩ) BUS (VOLTAGE) MAXIMUM AVERAGE CURRENT MAXIMUM PEAK CURRENT 63 12 ≤3A (Note 4) ≤7A (Note 5) 51 5 ≤1A ≤2A 48 3.3 ≤1A ≤1.25A 43 12 ≤3A (Note 4) ≤11A (Note 5) 40 5 ≤2A ≤2.5A Dual Dual or HUF76113T3ST 0.08 SOT223 Single 37 3.3 ≤1.5A ≤1.5A HUF76131SK8 0.05 SO-8 Single 17 12 ≤6A (Note 4) ≤25A (Note 5) 16 5 ≤5A (Note 4) ≤6A (Note 5) 15 3.3 ≤4A ≤4A 7 3.3 ≤9A (Note 4) ≤9A (Note 5) HUF76143S3S 0.31 TO-263 Single NOTES: 4. Maximum-Average-Current level meets or exceeds the Device-Bay specified level for a 30s “peak”. 5. Maximum-Peak-Current level meets or exceeds the Device-Bay specified level for a 100µs “transient”. The MOSFETs in Table 1 were selected based on the assumption that at most 2% the of the 5V or 3.3V-bus voltage could appear across the 5V or 3.3V MOSFET, and that at most 4% of the 12V-bus voltage could appear across the 12V MOSFET. The worst-case voltage drop occurs during a 100µs current transient given in the MaximumPeak-Current column. Longer transients may not be tolerable by the MOSFET depending on its junction temperature prior to the transient. power MOSFET. The result is a momentary dip in the rail voltage which can effect the device’s operation as well as the operation of any other device already connected and potentially the host system itself. Without the dv/dt-activated clamp, a decoupling capacitor would be needed between each power MOSFET drain and ground using up valuable board space and adding unnecessary cost. The HIP1020 solves this problem by providing a path for capacitivelycoupled current to reach ground. In most cases, the given Mounting-Pad Area is required to achieve the Maximum-Average-Current rating. It assumes 1oz. copper, zero air flow, and an ambient temperature not exceeding 50oC. The Mounting-Pad Area is the approximate area of a rectangle encompassing the MOSFET package and its leads. The rDS(ON) numbers assume the device has reached thermal equillibrium at the Maximum-AverageCurrent. In some cases, the thermal capabilities as well as rDS(ON) can be improved by using larger pads, heavier copper, air flow, or lower ambient temperature. Increasing the Rise Time Protection from Unwanted Turn On A dv/dt-activated clamp circuit is internally connected to LGATE (pin 4), and is active when the chip is not powered. It is activated when the voltage on either LGATE or HGATE rises too quickly, and it immediately provides a lowimpedance ground path for current from either gate pin. The purpose of the dv/dt-activated clamp circuit is to prevent unwanted turn on of the power MOSFETs during a hot insertion event. When a Device-Bay peripheral is inserted into the bay, the power pins on the peripheral are brought into contact with the already-energized mating contacts in the bay. This results in a very fast-rising voltage edge on the drains of the power MOSFETs which can inject current through the gate-to-drain capacitance and briefly turn on the 5 The HIP1020 has an internal-ramping charge pump that increases the voltage to the power MOSFETs in a predictable controlled manner allowing soft turn on of most types of loads. It is possible that some types of load would require slower turn on. This could arise when a load has a large capacitive component or for some other reason requires an extraordinarily high starting current. Without the external capacitor, C1 (see Figure 1), the ramp rate is about 5V/ms. A capacitor between HGATE and ground will slow the rise time of both gate voltages to a rate given by I HGATE C1 = ------------------- dv ------ dt (EQ.1) In Equation 1, C1 is the value of capacitor in Farads required to achieve a rise rate of dv/dt in V/s, and IHGATE is current output of pin 4 given in Amperes as shown in the “Electrical Specifications” section of this data sheet. Figures 2 through 5 show gate voltage waveforms for selected values of C1. HIP1020 Special Applications The HIP1020 is well suited to work with N-Channel MOSFETs controlling voltages other than 12V, 5V, or 3.3V provided three basic constraints are observed. The first constraint is that the bias voltage for the HIP1020 is either 12V or 5V. Chip operation at voltages significantly below 5V is not possible, while a bias voltage very much above 12V can unnecessarily stress the part. Operation between 5V and 12V can “confuse” the chip as it tries to determine whether to operate as a voltage doubler or voltage tripler. The final two constraints have to do with proper operation of the power MOSFETs. These constraints assume that a rail voltage, VRAIL, is to be switched using an N-Channel power MOSFET having a gate-to-source breakdown voltage of VBR and a threshold voltage of VTH. V TH < V GATE – V RAIL (EQ.2) V BR > V GATE – V RAIL (EQ.3) VGATE can be either VHGATE or VLGATE depending on which pin is connected to the power MOSFET and will be selected based on which gate voltage is most appropriate for the application. The requirement in Equation 2 is necessary to assure that the power MOSFET is fully enhanced. VTH should be the maximum data-sheet value needed to assure adequately low rDSON. The requirement in Equation 3 assures that the power MOSFET is protected from breakdown of the gate oxide. 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