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 Preliminary EUP2618 Triple Adjustable Output TFT-LCD DC-DC Converters
DESCRIPTION
The EUP2618 triple-output DC-DC converter provides the regulated voltages required by active-matrix, thin-film transistor (TFT) liquid-crystal displays (LCDs). One high-power DC-DC converter and two low-power charge pumps convert the 3.3V to 5V input supply voltage into three independent output voltages. The primary 1.2MHz DC-DC converter generates a boosted output voltage (VMAIN) up to 18V using ultra-small inductors and ceramic capacitors. The low-power control circuitry and the low on-resistance (0.2) of the integrated power MOSFET allows efficiency up to 92%. The dual charge pumps independently regulate one positive output (VPOS) and one negative output (VNEG). These low-power outputs use external diode and capacitor stages to regulate output voltages up to 40V and down to -40V. For EUP2618, the supply sequence is VMAIN first, VNEG next, and finally VPOS. The EUP2618 soft-starts each supply as soon as the previous supply finishes. The EUP2618 are available in the ultra-thin TSSOP-16 package.
FEATURES
1.2MHz Current-Mode PWM Boost Regulator Up to 18V Main High-Power Output 2.1A, 0.2 Power MOSFET 92% High Efficiency Dual Adjustable Charge-Pump Outputs Up to 40V Positive Output Down to -40V Negative Output Internal Power-up Sequencing 2.5V to 5.5V Input Range 0.1A Shutdown Current 0.7mA Quiescent Current Internal Soft-Start Power-Ready Output Ultra-Small External Components Thin TSSOP-16 Package
RoHS Compliant and 100% Lead (Pb)-Free
APPLICATIONS
TFT Active-Matrix LCD Displays Passive-Matrix LCD Displays PDAs Digital Still Cameras Camcorders
Typical Application Circuit
Figure 1.
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Preliminary
Block Diagram
EUP2618
Figure 2.
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Preliminary
Pin Configurations
Package Type Pin Configurations
EUP2618
TSSOP-16
Pin Description
PIN 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 NAME
RDY
FB COMP IN GND REF FBP FBN
SHDN
DESCRIPTION Active-Low, Open-Drain Output. Indicates all outputs are ready. The on-resistance is 125 (typ). Main Boost Regulator Feedback Input. Regulates to 1.25V nominal. Connect feedback resistive divider to analog ground (GND). Main Boost Compensation Network Connection. Supply Input. 2.5V to 5.5V input range. Bypass with a 0.1F capacitor between IN and GND, as close to the pins as possible. Analog Ground. Connect to power ground (PGND) underneath the IC. Internal Reference Bypass Terminal. Connect a 0.22F capacitor from this terminal to analog ground (GND). External load capability to 100A. Positive Charge-Pump Regulator Feedback Input. Regulates to 1.25V nominal. Connect feedback resistive divider to analog ground (GND). Negative Charge-Pump Regulator Feedback Input. Regulates to 0V nominal. Active-Low Logic-Level Shutdown Input. Connect SHDN to IN for normal operation. Negative Charge-Pump Driver Output. Output high level is VSUPN, and low level is TGND. Negative Charge-Pump Driver Supply Voltage. Bypass to TGND with a 0.1F capacitor. Positive Charge-Pump Driver Output. Output high level is VSUPP, and low level is TGND. Positive Charge-Pump Driver Supply Voltage. Bypass to TGND with a 0.1F capacitor. Power Ground of Charge-Pumps. Main Boost Regulator Power MOSFET n-Channel Drain. Connect output diode and output capacitor as close to PGND as possible. Power Ground of Main Boost.
DRVN SUPN DRVP SUPP TGND LX PGND
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Preliminary
Ordering Information
Order Number Package Type Marking
EUP2618
Operating Temperature range
EUP2618QIR1
TSSOP-16
xxxxx EUP2618
-40 C to 85C
EUP2618
1/4
1/4
1/4
1/4
Lead Free Code 1: Lead Free 0: Lead Packing R: Tape & Reel Operating temperature range I: Industry Standard Package Type Q: TSSOP
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Preliminary
Absolute Maximum Ratings
EUP2618
IN to GND ---------------------------------------------------------------------------- -0.3V to 6V DRVN to GND ---------------------------------------------------------- -0.3V to (VSUPN +0.3V) DRVP to GND ----------------------------------------------------------- -0.3V to (VSUPP +0.3V) PGND ,TGND to GND --------------------------------------------------------------------- 0.3V RDY ,SUPP,SUPN to GND -------------------------------------------------------- -0.3V to 14V LX to GND --------------------------------------------------------------------------- -0.3V to 19V COMP, SHDN ,REF, FB ,FBN, FBP to GND ------------------------ -0.3V to (VIN +0.3V) Operating Temperature --------------------------------------------------------- -40C to 85C Junction Temperature ------------------------------------------------------------------- 150C Storage Temperature ----------------------------------------------------------- -65C to150C Lead Temp (Soldering, 10sec) --- --------------------------------------------------260C
Electrical Characteristics
(Specfications in standard type face are for TA =25J and those with boldface type apply over the full Operating J Temperature Range (TA=-40 to J85 ). VIN=3.3V, VSUPP=VSUPN=10V ,GND=PGND=TGND=0, unless otherwise noted.) EUP2618 Parameter Conditions Unit Min. Typ. Max. Operating Power Input Supply Voltage Range VIN Under Voltage Lockout Falling Rising VFB=VFBP=1.4V, VFBN=0V , not switching VFB=1.1V, VFBP=1.4V, VFBN=0V switching V SHDN =GND 15J Hysteresis IVREF=100uA IVREF=100uA, VIN=2.5~5V IVREF=0~100uA 1.22 VFB=1.25V 2.5VQuiescent Current Shutdown Current Thermal Shutdown Reference Reference Voltage Line Regulation Load Regulation EA (Error Amplifier) Feedback Voltage Input Bias Current Feedback Voltage Line Regulation Error Amp Transconductance Error Amp Voltage Gain Oscillator Operating Frequency Maximum Duty N-Channel Switch Switch Current Limit
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Preliminary
Electrical Characteristics (continued)
EUP2618
(Specfications in standard type face are for TA =25J and those with boldface type apply over the full Operating Temperature Range (TA=-40J to 85J ). VIN=3.3V, VSUPP=VSUPN=10V ,GND=PGND=TGND=0, unless otherwise noted.) EUP2618 Parameter Conditions Unit Min. Typ. Max. Switch RDSON ILX=200mA 0.2 0.4 Switch Leakage Current Control Inputs Characteristics (SHDN) SHDN Low Threshold SHDN High Threshold SHDN Pin Pull Up Current Soft Start & Fault Detect Time Channel 1 Soft Start Time Channel 2 Soft Start Time Channel 3 Soft Start Time Channel 1 Fault Protect Trigger Time Channel 2 Fault Protect Trigger Time Channel 3 Fault Protect Trigger Time FB Fault Protection Voltage FBN Fault Protection Voltage FBP Fault Protection Voltage Charge Pump Regulator Characteristics VSUPP Input Supply Range VSUPN Input Supply Range FBN Threshold Voltage FBP Threshold Voltage FBN Input Bias Current FBP Input Bias Current Charge Pump Frequency OUT2 Switch R-on OUT3 Switch R-on Continuous Output Current PMOS NMOS PMOS NMOS IOUT2=10mA IOUT2=-10mA IOUT3=10mA IOUT3=-10mA VFBN=-0.05V VFBP=-1.5V 5 5 -50 1.208 -50 -50 fOSC/2 3 3 3 3 20 20 20 20 30 1.258 13.5 13.5 50 1.308 50 50 V V mV V nA nA kHz 1 0.08 1 14 3.5 3.5 55 14 14 1.1 0.13 1.1 1.2 0.18 1.2 ms ms ms ms ms ms V V V SHDN=GND 1.8 0.001 1 0.8 V V uA VLX=18V 0.01 20 uA
[ [ [ [
mA
Test Condition TA=25J
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Preliminary
Typical Characteristics
EUP2618
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Preliminary
EUP2618
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EUP2618
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Preliminary
Detailed Description
Main Boost Converter Operations In steady state operating and continuous conduction mode where the inductor current is continuous, the boost converter operates in two cycles. During the first cycle, the internal power FET turns on and the Schottky diode is reverse biased and cuts off the current flow to the output. The output current is supplied from the output capacitor. The voltage across the inductor is VIN and the inductor current ramps up in a rate of VIN/L, L is the inductance. The inductance is magnetized and energy is stored in the inductor. The change in inductor current is:
I L = T2 x V -V IN MAIN L
EUP2618
Dual Charge-Pump Regulator The EUP2618 contain two individual low-power charge pumps. One charge pump inverts the supply voltage (SUPN) and provides a regulated negative output voltage. The second charge pump doubles the supply voltage (SUPP) and provides a regulated positive output voltage. The EUP2618 contain internal p-channel and n-channel MOSFETs to control the power transfer. The internal MOSFETs switch at a constant 600kHz (0.5 x fOSC). Negative Charge Pump During the first half-cycle, the p-channel MOSFET turns on and the flying capacitor C5 charges to VSUPN minus a diode drop. During the second half-cycle, the p-channel MOSFET turns off, and the n-channel MOSFET turns on, level shifting C5. This connects C5 in parallel with the reservoir capacitor C6. If the voltage across C6 minus a diode drop is lower than the voltage across C5, charge flows from C5 to C6 until the diode (D5) turns off. The amount of charge transferred to the output is controlled by the variable n-channel on-resistance. Positive Charge Pump During the first half-cycle, the n-channel MOSFET turns on and charges the flying capacitor C3. This initial charge is controlled by the variable n-channel on resistance. During the second half-cycle, the n-channel MOSFET turns off and the p-channel MOSFET turns on, level shifting C3 by VSUPP volts. This connects C3 in parallel with the reservoir capacitor C4. If the voltage across C4 plus a diode drop (VPOS + VDIODE) is smaller than the level-shifted flying capacitor voltage (VC3 + VSUPP), charge flows from C3 to C4 until the diode (D3) turns off. Shutdown A logic-low level on SHDN disables all three EUP2618 converters and the reference. When shut down, supply current drops to 0.1A to maximize battery life and the reference is pulled to ground. The output capacitance and load current determine the rate at which each output voltage will decay. A logic-level high on SHDN power activates the EUP2618 (see the Power-Up Sequencing section). Do not leave SHDN floating. If unused, connect SHDN to GND. Power-Up Sequencing Upon power-up or exiting shutdown, the EUP2618 start their respective power-up sequences. The reference powers up first, then the main DC-DC step-up converter powers up with softstart enabled. Once the main step-up converter reaches regulation, the negative charge pump turns on. The positive charge pump starts up. Finally, when the positive output voltage reaches 88% of its nominal value (VFBP > 1.1V), the active-low ready signal ( RDY ) goes low (see the Power Ready section).
T2 =
1- D F LX
For stable operation, the same amount of energy stored in the inductor must be taken out. The change in inductor current during the two cycles must be the same. I1+I2=0
D F LX V V -V MAIN = 0 IN + 1 - D x IN L L F LX
x
V MAIN = 1 1- D V IN
Output Voltage An external feedback resistor divider is required to divide the output voltage down to the nominal 1.25V reference voltage. The current drawn by the resistor network should be limited to maintain the overall converter efficiency. The maximum value of the resistor network is limited by the feedback input bias current and the potential for noise being coupled into the feedback pin. Selecting R2 in the range of 10k to 50 k. The boost converter output voltage s determined by the relationship:
R V =V x 1 + 1 MAIN FB R2
The nominal VFB voltage is 1.25V
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Preliminary
Power Ready Power ready is an open-drain output. When the power up sequence is properly completed, the MOSFET turns on and pulls RDY low with a typical 125 on-resistance. If a fault is detected, the internal open-drain MOSFET appears as a high impedance. Connect a 100k pullup resistor between RDY and IN for a logic level output. Fault Detection Once RDY is low and if any output falls below its fault-detection threshold, RDY goes high impedance. For the main boost converter, the fault threshold is 88% of its nominal value (VFB < 1.1V). For the negative charge pump, the fault threshold is approximately 90% of its nominal value (VFBN < 130mV). For the positive charge pump, the fault threshold is 88% of its nominal value (VFBP < 1.1V). Once an output faults, all outputs later in the power sequence shut down until the faulted output rises above its power-up threshold. Inductor Selection The inductor selection determines the output ripple voltage, transient response, output current capability, and efficiency. Its selection depends on the input voltage, output voltage, switching frequency, and maximum output current. For most applications, a 4.7H to 10uH inductor is recommended for 1.2MHz application. The inductor maximum DC current specification must be greater than the peak inductor current required by the regulator. The peak inductor current can be calculated:
I = I
EUP2618
Input Capacitor The value of the input capacitor depends the input and output voltages, the maximum output current, the inductor value and the noise allowed to put back on the input line. For most applications, a minimum 10F is required. For applications that run close to the maximum output current limit, input capacitor in the range of 22F to 47F is recommended. The EUP2618 is powered from the VIN. High frequency 0.1F by-pass cap is recommended to be close to the VIN pin to reduce supply line noise and ensure stable operation. Rectifier Diode Use a Schottky diode with an average current rating equal to or greater than the peak inductor current, and a voltage rating at least 1.5 times the main output voltage (VMAIN). Charge Pump
Efficiency Considerations
The efficiency characteristics of the EUP2618 regulated charge pumps are similar to a linear regulator. They are dominated by quiescent current at low output currents and by the input voltage at higher output currents (see the Typical Operating Characteristics). So the maximum efficiency can be approximated by:
Efficiency V NEG /[V x N]; SUPN
for the negative charge pump
Efficiency V POS /[V x ( N + 1)]; SUPP
MAIN
L(PEAK)
xV V x (V -V ) IN MAIN IN MAIN + 1/2 x LxV x FREQ V MAIN IN
for the positive charge pump where N is the number of charge-pump stages. Output Voltage Selection Adjust the positive output voltage by connecting a voltagedivider from the output (VPOS) to FBP to GND (see the Typical Operating Circuit). Adjust the negative output voltage by connecting a voltage-divider from the output (VNEG) to FBN to REF. Select R4 and R6 in the 50k to 100k range. Higher resistor values improve efficiency at low output current but increase output-voltage error due to the feedback input bias current. Calculate the remaining resistors with the following equations:
R3 = R4[(V R5 = R6(V POS /V ) - 1] REF
Output Capacitor Low ESR capacitors should be used to minimized the output voltage ripple. Multilayer ceramic capacitors (X5R and X7R) are preferred for the output capacitors because of their lower ESR and small packages. Tantalum capacitors with higher ESR can also be used. The output ripple can be calculated as:
I xD V = MAIN +I x ESR O MAIN F xC LX O
Choose an output capacitor to satisfy the output ripple and load transient requirement. A 10F to 22F ceramic capacitor is suitable for most application. For noise sensitive application, a 0.1F placed in parallel with the larger output capacitor is recommended to reduce the switching noise coupled from the LX switching node.
POS
/V ) REF
where VREF = 1.25V. VPOS can range from VSUPP to 40V, and VNEG can range from 0 to -40V.
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Preliminary
Flying Capacitor Increasing the flying capacitor's value reduces the output current capability. Above a certain point, increasing the capacitance has a negligible effect because the output current capability becomes dominated by the internal switch resistance and the diode impedance. Start with 0.1F ceramic capacitors. Smaller values can be used for low-current applications. Charge-Pump Output Capacitor Increasing the output capacitance or decreasing the ESR reduces the output ripple voltage and the peak-to-peak transient voltage. Use the following equation to approximate the required capacitor value:
C OUT [I OUT /(600kHz x VRIPPLE )]
EUP2618
Use a bypass capacitor with a value equal to or greater than the flying capacitor. Place the capacitor as close to the IC as possible. Connect directly to TGND.
Charge-Pump Input Capacitor
Use a bypass capacitor with a value equal to or greater than the flying capacitor. Place the capacitor as close to the IC as possible. Connect directly to GND.
Rectifier Diode
Use Schottky diodes with a current rating equal to or greater than 4 times the average output current, and a voltage rating at least 1.5 times VSUPP for the positive charge pump and VSUPN for the negative charge pump. PC Board Layout and Grounding Careful printed circuit layout is extremely important to minimize ground bounce and noise. First, place the main boost-converter output diode and output capacitor less than 0.2in (5mm) from the LX and PGND pins with wide traces and no vias. Then place 0.1F ceramic bypass capacitors near the charge-pump input pins (SUPP and SUPN) to the PGND pin. Keep the charge pump circuitry as close to the IC as possible, using wide traces and avoiding vias when possible. Locate all feedback resistive dividers as close to their respective feedback pins as possible. The PC board should feature separate GND and PGND areas connected at only one point under the IC. To maximize output power and efficiency and to minimize output-power ripple voltage, use extra wide power ground traces and solder the IC's power ground pin directly to it. Avoid having sensitive traces near the switching nodes and high-current lines.
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Preliminary
Packaging Information
TSSOP-16
EUP2618
SYMBOLS A A1 b E1 D E e L
MILLIMETERS MIN. MAX. 1.20 0.00 0.15 0.19 0.30 4.40 5.00 6.20 6.60 0.65 0.45 0.75
INCHES MIN. 0.000 0.007 0.173 0.197 0.244 0.026 0.018 0.030 0.260 MAX. 0.047 0.006 0.012
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