LT1776 Wide Input Range, High Efficiency, Step-Down Switching Regulator U DESCRIPTION FEATURES Wide Input Range: 7.4V to 40V Tolerates Input Transients to 60V 700mA Peak Switch Rating Adaptive Switch Drive Maintains Efficiency at High Load Without Pulse Skipping at Light Load True Current Mode Control 200kHz Fixed Operating Frequency Synchronizable to 400kHz Low Supply Current in Shutdown: 30A Available in 8-Pin SO and PDIP Packages U APPLICATIONS Automotive DC/DC Converters Cellular Phone Battery Charger Accessories IEEE 1394 Step-Down Converters The LT(R)1776 is a wide input range, high efficiency Buck (step-down) switching regulator. The monolithic die includes all oscillator, control and protection circuitry. The part can accept input voltages as high as 60V and contains an output switch rated at 700mA peak current. Current mode control delivers excellent dynamic input supply rejection and short-circuit protection. The LT1776 contains several features to enhance efficiency. The internal control circuitry is normally powered via the VCC pin, thereby minimizing power drawn directly from the VIN supply (see Applications Information). The action of the LT1776 switch circuitry is also load dependent. At medium to high loads, the output switch circuitry maintains fast rise time for good efficiency. At light loads, rise time is deliberately reduced to avoid pulse skipping behavior. The available SO-8 package and 200kHz switching frequency allow for minimal PC board area requirements. , LTC and LT are registered trademarks of Linear Technology Corporation. U TYPICAL APPLICATION Efficiency vs VIN and ILOAD VIN 8V TO 40V 5 + 90 VIN SHDN VCC VSW 39F 63V 2 80 100H* 3 + MBR160 LT1776 100F 10V 5V 400mA 36.5k 1% 7 6 FB 8 VC SYNC 2200pF GND 12.1k 1% 4 *43T #30 ON MAGNETICS MPP #55030 Figure 1 60 50 40 100pF 22k 70 EFFICIENCY (%) 1 VIN = 10V VIN = 20V VIN = 30V VIN = 40V 30 20 1776 F01 1 10 100 LOAD CURRENT (mA) 1000 1776 TA01 1 LT1776 W U U U W W W ABSOLUTE MAXIMUM RATINGS PACKAGE/ORDER INFORMATION (Note 1) Supply Voltage (Note 5) .......................................... 60V Switch Voltage (Note 5) ........................................... 60V SHDN, SYNC Pin Voltage ........................................... 7V VCC Pin Voltage ....................................................... 30V FB Pin Voltage ........................................................... 3V Operating Junction Temperature Range LT1776C ................................................ 0C to 125C LT1776I ............................................ - 40C to 125C Storage Temperature Range ................. - 65C to 150C Lead Temperature (Soldering, 10 sec).................. 300C ORDER PART NUMBER TOP VIEW SHDN 1 8 VC VCC 2 7 FB VSW 3 6 SYNC GND 4 5 VIN N8 PACKAGE 8-LEAD PDIP S8 PACKAGE 8-LEAD PLASTIC SO LT1776CN8 LT1776CS8 LT1776IN8 LT1776IS8 S8 PART MARKING TJMAX = 125C, JA = 130C/ W (N8) TJMAX = 125C, JA = 110C/ W (S8) 1776 1776I Consult factory for Military grade parts. ELECTRICAL CHARACTERISTICS The denotes specifications which apply over the full operating temperature range, otherwise specifications are TA = 25C. VIN = 40V, VSW open, VCC = 5V, VC = 1.4V unless otherwise noted. SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS 6.7 7.0 7.4 V V Power Supplies VIN(MIN) Minimum Input Voltage Thermally Limited Continuous Operating Voltage IVIN VIN Supply Current 40 VC = 0V 620 800 900 A A 3.2 4.0 5.0 mA mA IVCC VCC Supply Current VC = 0V VVCC V VCC Dropout Voltage (Note 2) 2.8 3.1 V Shutdown Mode IVIN VSHDN = 0V 30 50 75 A A 1.255 1.265 V V Feedback Amplifier VREF Reference Voltage IIN FB Pin Input Bias Current gm Feedback Amplifier Transconductance ISRC, ISNK VCL 1.225 1.215 1.240 600 1500 nA 650 400 200 1000 1500 mho mho 60 45 100 170 220 A A lc = 10A Feedback Amplifier Source or Sink Current Feedback Amplifier Clamp Voltage Reference Voltage Line Regulation 2.0 12V VIN 60V 0.01 Voltage Gain V 200 600 %/V V/V Output Switch VON Output Switch On Voltage ISW = 0.5A ILIM Switch Current Limit (Note 3) 1.0 1.5 V 0.55 0.70 1.0 A 0.9 1.1 1.25 Current Amplifier Control Pin Threshold Control Voltage to Switch Transconductance 2 Duty Cycle = 0% 2 V A/V LT1776 ELECTRICAL CHARACTERISTICS The denotes specifications which apply over the full operating temperature range, otherwise specifications are TA = 25C. VIN = 40V, VSW open, VCC = 5V, VC = 1.4V unless otherwise noted. SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS 180 170 200 220 230 kHz kHz 85 90 % 300 ns VC Pin Boost Threshold 1.35 V dV/dt Below Threshold 0.2 V/ns dV/dt Above Threshold 1.6 V/ns Timing f Switching Frequency Maximum Switch Duty Cycle tON(MIN) Minimum Switch On Time High dV/dt Mode, RL = 39 (Note 4) Boost Operation Sync Function Minimum Sync Amplitude Synchronization Range 1.5 (Note 6) 250 SYNC Pin Input R 2.2 V 400 kHz 40 k SHDN Pin Function VSHDN Shutdown Mode Threshold 0.5 ISHDN 0.2 0.8 Upper Lockout Threshold Switching Action On 1.260 Lower Lockout Threshold Switching Action Off 1.245 Shutdown Pin Current VSHDN = 0V VSHDN = 1.25V Note 1: Absolute Maximum Ratings are those values beyond which the life of a device may be impaired. Note 2: Control circuitry powered from VCC. Note 3: Switch current limit is DC trimmed and tested in production. Inductor dl/dt rate will cause a somewhat higher current limit in actual application. Note 4: Minimum switch on time is production tested with a 39 resistive load to ground. 12 2.5 V V V V 20 10 A A Note 5: Parts are guaranteed to survive 60V on VIN and VSW. However, thermal constraints will limit VIN in some applications, depending primarily on maximum output current and switching frequency. See Applications section for more information. Note 6: Internal oscillator is guaranteed to sync up to 400kHz. However, thermal constraints and/or controllability issues may place a lower limit on switching frequency in actual usage. See Applications section for more information. 3 LT1776 U W TYPICAL PERFORMANCE CHARACTERISTICS Minimum Input Voltage vs Temperature Switch Current Limit vs Duty Cycle Switch-On Voltage vs Switch Current 7.4 1.50 7.2 1.25 1000 7.0 6.8 6.6 6.4 SWITCH CURRENT LIMIT (mA) SWITCH VOLTAGE (V) INPUT VOLTAGE (V) TA = 25C 25C - 55C 1.00 0.75 125C 0.50 0.25 6.2 6.0 -50 -25 50 25 75 0 TEMPERATURE (C) 100 0 125 200 300 400 500 600 SWITCH CURRENT (mA) 100 700 600 500 400 300 1.30 0 1.28 -5 -10 25C -55C 125C -15 0 1 3 4 2 SHDN PIN VOLTAGE (V) 1.20 -50 -25 5 195 190 75 100 125 1776 G07 125 600 2.00 1.75 1.50 1.25 1.00 0.75 -50 -25 100 Switch Minimum On-Time vs Temperature 2.25 0 25 50 75 100 125 TEMPERATURE (C) TEMPERATURE (C) 50 25 75 0 TEMPERATURE (C) LT1776 G06 SWITCH MINIMUM ON-TIME (ns) 200 50 1.24 1776 G05 MINIMUM SYNCHRONIZATION VOLTAGE (V) 205 25 LOWER THRESHOLD Minimum Synchronization Voltage vs Temperature 210 0 UPPER THRESHOLD 1.26 1.22 -20 125 215 10 20 30 40 50 60 70 80 90 100 DUTY CYCLE (%) 1776 G03 5 Switching Frequency vs Temperature SWITCHING FREQUENCY (kHz) 0 SHDN Pin Lockout Thresholds vs Temperature LT1776 G04 4 700 SHDN PIN VOLTAGE (V) SHDN PIN INPUT CURRENT (A) SHDN PIN VOLTAGE (mV) 800 185 -50 -25 200 SHDN Pin Input Current vs Voltage 900 100 400 1776 G02 SHDN Pin Shutdown Threshold vs Temperature 50 25 75 0 TEMPERATURE (C) 600 0 0 1776 G01 200 -50 -25 800 1776 G08 500 VIN = 40V RL = 39 FB = 400 300 200 100 0 -50 -25 50 25 75 0 TEMPERATURE (C) 100 125 1776 G09 LT1776 U W TYPICAL PERFORMANCE CHARACTERISTICS VC Pin Switching Threshold, Boost Threshold, Clamp Voltage vs Temperature Feedback Amplifier Output Current vs FB Pin Voltage VC PIN VOLTAGE (V) 2.0 CLAMP VOLTAGE 1.8 1.6 BOOST THRESHOLD 1.4 SWITCHING THRESHOLD 1.2 1.0 0.8 -50 -25 50 25 75 0 TEMPERATURE (C) 100 125 750 100 25C -55C 125C 50 TRANSCONDUCTANCE (mho) FEEDBACK AMPLIFIER OUTPUT CURRENT (A) 2.2 Error Amplifier Transconductance vs Temperature 0 -50 -100 700 650 600 550 500 450 -150 1.0 1.1 1.3 1.4 1.2 FB PIN VOLTAGE (V) LT1776 G10 1.5 1776 G11 400 -50 -25 50 25 75 0 TEMPERATURE (C) 100 125 LT1776 G12 U U U PIN FUNCTIONS SHDN (Pin 1): When pulled below the shutdown mode threshold, nominally 0.30V, this pin turns off the regulator and reduces VIN input current to a few tens of microamperes (shutdown mode). When this pin is held above the shutdown mode threshold, but below the lockout threshold, the part will be operational with the exception that output switching action will be inhibited (lockout mode). A user-adjustable undervoltage lockout can be implemented by driving this pin from an external resistor divider to VIN. This action is logically "ANDed" with the internal UVLO, set at nominally 6.7V, such that minimum VIN can be increased above 6.7V, but not decreased (see Applications Information). If unused, this pin should be left open. However, the high impedance nature of this pin renders it susceptible to coupling from the high speed VSW node, so a small capacitor to ground, typically 100pF or so is recommended when the pin is left "open". VCC (Pin 2): This pin is used to power the internal control circuitry off of the switching supply output. Proper use of this pin enhances overall power supply efficiency. During start-up conditions, internal control circuitry is powered directly from VIN. If the output capacitor is located more than one inch from the VCC pin, a separate 0.1F bypass capacitor to ground may be required right at the pin. VSW (Pin 3): This is the emitter node of the output switch and has large currents flowing through it. This node moves at a high dV/dt rate, especially when in "boost" mode. Keep the traces to the switching components as short as possible to minimize electromagnetic radiation and voltage spikes. GND (Pin 4): This is the device ground pin. The internal reference and feedback amplifier are referred to it. Keep the ground path connection to the FB divider and the VC compensation capacitor free of large ground currents. VIN (Pin 5): This is the high voltage supply pin for the output switch. It also supplies power to the internal control circuitry during start-up conditions or if the VCC pin is left open. A high quality bypass capacitor which meets the input ripple current requirements is needed here. (See Applications Information). SYNC (Pin 6): Pin used to synchronize internal oscillator to the external frequency reference. It is directly logic compatible and can be driven with any signal between 5 LT1776 U U U PIN FUNCTIONS abnormally low, e.g., 2/3 of normal or less. This feature helps maintain proper short-circuit protection. 10% and 90% duty cycle. The sync function is internally disabled if the FB pin voltage is low enough to cause oscillator slowdown. If unused, this pin should be grounded. VC (Pin 8): This is the control voltage pin which is the output of the feedback amplifier and the input of the current comparator. Frequency compensation of the overall loop is effected by placing a capacitor, (or in most cases a series RC combination) between this node and ground. FB (Pin 7): This is the inverting input to the feedback amplifier. The noninverting input of this amplifier is internally tied to the 1.24V reference. This pin also slows down the frequency of the internal oscillator when its voltage is W BLOCK DIAGRA VCC 2 R1 5 VIN 3 VSW RSENSE VBG SHDN 1 BIAS VB OSC SYNC 6 LOGIC Q3 I COMP SWDR Q4 SWDR SWON BOOST SWOFF Q2 Q1 D1 GND 4 SWON I BOOST COMP I I VC 8 FB AMP FB 7 gm VTH BOOST I SWOFF Q5 VBG 1776 BD 6 LT1776 W UW TIMING DIAGRAMS High dV/dt Mode Low dV/dt Mode VIN VIN VSW VSW 0 0 SWDR SWDR SWON SWON BOOST BOOST SWOFF SWOFF 1776 TD01 1776 TD02 U OPERATIO The LT1776 is a current mode switching regulator IC that has been optimized for high efficiency operation in high input voltage, low output voltage buck topologies. The Block Diagram shows an overall view of the system. Several of the blocks are straightforward and similar to those found in traditional designs, including: Internal Bias Regulator, Oscillator and Feedback Amplifier. The novel portion includes an elaborate Output Switch section and Logic Section to provide the control signals required by the switch section. The LT1776 operates much the same as traditional current mode switchers, the major difference being its specialized output switch section. Due to space constraints, this discussion will not reiterate the basics of current mode switcher/controllers and the "buck" topology. A good source of information on these topics is Application Note 19. Output Switch Theory One of the classic problems in delivering low output voltage from high input voltage at good efficiency is that minimizing AC switching losses requires very fast voltage (dV/dt) and current (dI/dt) transition at the output device. This is in spite of the fact that in a bipolar implementation, slow lateral PNPs must be included in the switching signal path. Fast positive-going slew rate action is provided by lateral PNP Q3 driving the Darlington arrangement of Q1 and Q2. The extra available from Q2 greatly reduces the drive requirements of Q3. Although desirable for dynamic reasons, this topology alone will yield a large DC forward voltage drop. A second lateral PNP, Q4, acts directly on the base of Q1 to reduce the voltage drop after the slewing phase has taken place. To achieve the desired high slew rate, PNPs Q3 and Q4 are "force-fed" packets of charge via the current sources controlled by the boost signal. Please refer to the High dV/dt Mode Timing Diagram. A typical oscillator cycle is as follows: The logic section first generates an SWDR signal that powers up the current comparator and allows it time to settle. About 1s later, the SWON signal is asserted and the BOOST signal is pulsed for a few hundred nanoseconds. After a short delay, the VSW pin slews rapidly to VIN. Later, after the peak switch current indicated by the control voltage VC has been reached (current mode control), the SWON and SWDR signals are turned off, and SWOFF is pulsed for several hundred nanoseconds. The use of an explicit turn-off device, i.e., Q5, improves turn-off response time and thus aids both controllability and efficiency. 7 LT1776 U OPERATIO The system as previously described handles heavy loads (continuous mode) at good efficiency, but it is actually counterproductive for light loads. The method of jamming charge into the PNP bases makes it difficult to turn them off rapidly and achieve the very short switch ON times required by light loads in discontinuous mode. Furthermore, the high leading edge dV/dt rate similarly adversely affects light load controllability. The solution is to employ a "boost comparator" whose inputs are the VC control voltage and a fixed internal threshold reference, VTH. (Remember that in a current mode switching topology, the VC voltage determines the peak switch current.) When the VC signal is above VTH, the previously described "high dV/dt" action is performed. When the VC signal is below VTH, the boost pulses are absent, as can be seen in the Low dV/dt Mode Timing Diagram. Now the DC current, activated by the SWON signal alone, drives Q4 and this transistor drives Q1 by itself. The absence of a boost pulse, plus the lack of a second NPN driver, result in a much lower slew rate which aids light load controllability. A further aid to overall efficiency is provided by the specialized bias regulator circuit, which has a pair of inputs, VIN and VCC. The VCC pin is normally connected to the switching supply output. During start-up conditions, the LT1776 powers itself directly from VIN. However, after the switching supply output voltage reaches about 2.9V, the bias regulator uses this supply as its input. Previous generation buck controller ICs without this provision typically required hundreds of milliwatts of quiescent power when operating at high input voltage. This both degraded efficiency and limited available output current due to internal heating. U W U U APPLICATIONS INFORMATION Selecting a Power Inductor There are several parameters to consider when selecting a power inductor. These include inductance value, peak current rating (to avoid core saturation), DC resistance, construction type, physical size, and of course, cost. In a typical application, proper inductance value is dictated by matching the discontinuous/continuous crossover point with the LT1776 internal low-to-high dV/dt threshold. This is the best compromise between maintaining control with light loads while maintaining good efficiency with heavy loads. The fixed internal dV/dt threshold has a nominal value of 1.4V, which referred to the VC pin threshold and control voltage to switch transconductance, corresponds to a peak current of about 200mA. Standard buck converter theory yields the following expression for inductance at the discontinuous/continuous crossover: V V - V L = OUT IN OUT VIN f * IPK 8 For example, substituting 40V, 5V, 200mA and 200kHz respectively for VIN, VOUT, IPK and f yields a value of about 100H. Note that the left half of this expression is independent of input voltage while the right half is only a weak function of VIN when VIN is much greater than VOUT. This means that a single inductor value will work well over a range of "high" input voltage. And although a progressively smaller inductor is suggested as VIN begins to approach VOUT, note that the much higher ON duty cycles under these conditions are much more forgiving with respect to controllability and efficiency issues. Therefore when a wide input voltage range must be accommodated, say 10V to 40V for 5VOUT, the user should choose an inductance value based on the maximum input voltage. Once the inductance value is decided, inductor peak current rating and resistance need to be considered. Here, the inductor peak current rating refers to the onset of saturation in the core material, although manufacturers sometimes specify a "peak current rating" which is derived from a worst-case combination of core saturation and self-heating effects. Inductor winding resistance alone LT1776 U W U U APPLICATIONS INFORMATION limits the inductor's current carrying capability as the I2R power threatens to overheat the inductor. If applicable, remember to include the condition of output short circuit. Although the peak current rating of the inductor can be exceeded in short-circuit operation, as core saturation per se is not destructive to the core, excess resistive selfheating is still a potential problem. The final inductor selection is generally based on cost, which usually translates into choosing the smallest physical size part that meets the desired inductance value, resistance and current carrying capability. An additional factor to consider is that of physical construction. Briefly stated, "open" inductors built on a rod- or barrel-shaped core generally offer the smallest physical size and lowest cost. However their open construction does not contain the resulting magnetic field, and they may not be acceptable in RFI-sensitive applications. Toroidal style inductors, many available in surface mount configuration, offer improved RFI performance, generally at an increase in cost and physical size. And although custom design is always a possibility, most potential LT1776 applications can be handled by the array of standard, off-the-shelf inductor products offered by the major suppliers. Selecting Freewheeling Diode Highest efficiency operation requires the use of a Schottky type diode. DC switching losses are minimized due to its low forward voltage drop, and AC behavior is benign due to its lack of a significant reverse recovery time. Schottky diodes are generally available with reverse voltage ratings of 60V and even 100V, and are price competitive with other types. The use of so-called "ultrafast" recovery diodes is generally not recommended. When operating in continuous mode, the reverse recovery time exhibited by "ultrafast" diodes will result in a slingshot type effect. The power internal switch will ramp up VIN current into the diode in an attempt to get it to recover. Then, when the diode has finally turned off, some tens of nanoseconds later, the VSW node voltage ramps up at an extremely high dV/dt, perhaps 5 to even 10V/ns ! With real world lead inductances, the VSW node can easily overshoot the VIN rail. This can result in poor RFI behavior and if the overshoot is severe enough, damage the IC itself. Selecting Bypass Capacitors The basic topology as shown in Figure 1 uses two bypass capacitors, one for the VIN input supply and one for the VOUT output supply. User selection of an appropriate output capacitor is relatively easy, as this capacitor sees only the AC ripple current in the inductor. As the LT1776 is designed for buck or step-down applications, output voltage will nearly always be compatible with tantalum type capacitors, which are generally available in ratings up to 35V or so. These tantalum types offer good volumetric efficiency and many are available with specified ESR performance. The product of inductor AC ripple current and output capacitor ESR will manifest itself as peak-to-peak voltage ripple on the output node. (Note: If this ripple becomes too large, heavier control loop compensation, at least at the switching frequency, may be required on the VC pin.) The most demanding applications, requiring very low output ripple, may be best served not with a single extremely large output capacitor, but instead by the common technique of a separate L/C lowpass post filter in series with the output. (In this case, "Two caps are better than one".) The input bypass capacitor is normally a more difficult choice. In a typical application e.g., 40VIN to 5VOUT, relatively heavy VIN current is drawn by the power switch for only a small portion of the oscillator period (low ON duty cycle). The resulting RMS ripple current, for which the capacitor must be rated, is often several times the DC average VIN current. Similarly, the "glitch" seen on the VIN supply as the power switch turns on and off will be related to the product of capacitor ESR, and the relatively high instantaneous current drawn by the switch. To compound these problems is the fact that most of these applications will be designed for a relatively high input voltage, for which tantalum capacitors are generally unavailable. Relatively bulky "high frequency" aluminum electrolytic types, specifically constructed and rated for switching supply applications, may be the only choice. 9 LT1776 U W U U APPLICATIONS INFORMATION Input Voltage vs Operating Frequency Considerations The absolute maximum input supply voltage for the LT1776 is specified at 60V. This is based solely on internal semiconductor junction breakdown effects. Due to internal power dissipation, the actual maximum VIN achievable in a particular application may be less than this. A detailed theoretical basis for estimating internal power loss is given in the section, Thermal Considerations. Note that AC switching loss is proportional to both operating frequency and output current. The majority of AC switching loss is also proportional to the square of input voltage. For example, while the combination of VIN = 40V, VOUT = 5V at 500mA and fOSC = 200kHz may be easily achievable, simultaneously raising VIN to 60V and fOSC to 400kHz is not possible. Nevertheless, input voltage transients up to 60V can usually be accommodated, assuming the resulting increase in internal dissipation is of insufficient time duration to raise die temperature significantly. A second consideration is controllability. A potential limitation occurs with a high step-down ratio of VIN to VOUT, as this requires a correspondingly narrow minimum switch ON time. An approximate expression for this (assuming continuous mode operation) is given as follows: M in tON = VOUT + VF ( ) VIN fOSC where: VIN = input voltage VOUT = output voltage VF = Schottky diode forward drop fOSC = switching frequency It is important to understand the nature of minimum switch ON time as given in the data sheet. This test is intended to mimic behavior under short-circuit conditions. It is performed with the VC control voltage at its clamp level (VCL) and uses a fixed resistive load from VSW to ground for simplicity. The resulting ON time behavior is overconservative as a general operating design value for two reasons. First, actual power supply application circuits present an inductive load to the VSW node. The 10 resulting ramping current behavior helps overdrive the current comparator (current mode switching) and reduce its propagation delay, hastening output switch turnoff. Second, and more importantly, actual power supply operation involves a feedback amplifier that adjusts the VC node control voltage to maintain proper output voltage. As progressively shorter ON times are required, the feedback loop acts to reduce VC, and the resulting overdrive further reduces the propagation delay in the current comparator. A suggested worst-case limit for minimum switch ON time in actual operation is 350ns. A potential controllability problem arises if the LT1776 is called upon to produce an ON time shorter than its ability. Feedback loop action will lower then reduce the VC control voltage to the point where some sort of cycle-skipping or odd/even cycle behavior is exhibited. In summary: 1. Be aware that the simultaneous requirements of high VIN, high IOUT and high fOSC may not be achievable in practice due to internal dissipation. The Thermal Considerations section offers a basis to estimate internal power. In questionable cases a prototype supply should be built and exercised to verify acceptable operation. 2. The simultaneous requirements of high VIN, low VOUT and high fOSC can result in an unacceptably short minimum switch ON time. Cycle skipping and/or odd/ even cycle behavior will result although correct output voltage is usually maintained. Minimum Load Considerations As discussed previously, a lightly loaded LT1776 with VC pin control voltage below the boost threshold will operate in low dV/dt mode. This affords greater controllability at light loads, as minimum tON requirements are relaxed. However, some users may be indifferent to pulse skipping behavior, but instead may be concerned with maintaining maximum possible efficiency at light loads. This requirement can be satisfied by forcing the part into Burst ModeTM operation. The use of an external comparator whose Burst Mode is a trademark of Linear Technology Corporation. LT1776 U W U U APPLICATIONS INFORMATION Maximum Load/Short-Circuit Considerations The LT1776 is a current mode controller. It uses the VC node voltage as an input to a current comparator which turns off the output switch on a cycle-by-cycle basis as this peak current is reached. The internal clamp on the VC node, nominally 2V, then acts as an output switch peak current limit. This action becomes the switch current limit specification. The maximum available output power is then determined by the switch current limit. A potential controllability problem could occur under short-circuit conditions. If the power supply output is short circuited, the feedback amplifier responds to the low output voltage by raising the control voltage, VC, to its peak current limit value. Ideally, the output switch would be turned on, and then turned off as its current exceeded the value indicated by VC. However, there is finite response time involved in both the current comparator and turnoff of the output switch. These result in a minimum ON time tON(MIN). When combined with the large ratio of VIN to (VF + I * R), the diode forward voltage plus inductor I * R voltage drop, the potential exists for a loss of control. Expressed mathematically the requirement to maintain control is: V +I*R f * tON F VIN where: f = switching frequency tON = switch ON time VF = diode forward voltage VIN = Input voltage I * R = inductor I * R voltage drop If this condition is not observed, the current will not be limited at IPK, but will cycle-by-cycle ratchet up to some higher value. Using the nominal LT1776 clock frequency of 200KHz, a VIN of 40V and a (VF + I * R) of say 0.7V, the maximum tON to maintain control would be approximately 90ns, an unacceptably short time. The solution to this dilemma is to slow down the oscillator when the FB pin voltage is abnormally low thereby indicating some sort of short-circuit condition. Figure 2 shows the typical response of Oscillator Frequency vs FB divider Thevenin voltage and impedance. Oscillator frequency is unaffected until FB voltage drops to about 2/3 of its normal value. Below this point the oscillator frequency decreases roughly linearly down to a limit of about 30kHz. This lower oscillator frequency during short-circuit conditions can then maintain control with the effective minimum ON time. A further potential problem with short-circuit operation might occur if the user were operating the part with its oscillator slaved to an external frequency source via the SYNC pin. However, the LT1776 has circuitry that automatically disables the sync function when the oscillator is slowed down due to abnormally low FB voltage. 200 RTH = 22k 150 RTH = 10k fOSC (kHz) output controls the shutdown pin allows high efficiency at light loads through Burst Mode operation behavior (see Typical Applications and Figure 8). RTH = 4.7k 100 RTH 50 LT1776 FB 0 0 0.25 0.50 0.75 1.00 FB DIVIDER THEVENIN VOLTAGE (V) 1.25 1776 F02 Figure 2. Oscillator Frequency vs FB Divider Thevenin Voltage and Impedance Feedback Divider Considerations An LT1776 application typically includes a resistive divider between VOUT and ground, the center node of which drives the FB pin to the reference voltage VREF. This establishes a fixed ratio between the two resistors, but a second degree of freedom is offered by the overall impedance level of the resistor pair. The most obvious effect this has is one of efficiency--a higher resistance feedback divider will waste less power and offer somewhat higher efficiency, especially at light load. 11 LT1776 U W U U APPLICATIONS INFORMATION However, remember that oscillator slowdown to achieve short-circuit protection (discussed above) is dependent on FB pin behavior, and this in turn, is sensitive to FB node external impedance. Figure 2 shows the typical relationship between FB divider Thevenin voltage and impedance, and oscillator frequency. This shows that as feedback network impedance increases beyond 10k, complete oscillator slowdown is not achieved, and short-circuit protection may be compromised. And as a practical matter, the product of FB pin bias current and larger FB network impedances will cause increasing output voltage error. (Nominal cancellation for 10k of FB Thevenin impedance is included internally.) Thermal Considerations Care should be taken to ensure that the worst-case input voltage and load current conditions do not cause excessive die temperatures. The packages are rated at 110C/W for the 8-pin SO (S8) and 130C/W for 8-pin PDIP (N8). Quiescent power is given by: PQ = IIN * VIN + IVCC * VOUT (This assumes that the VCC pin is connected to VOUT.) Power loss internal to the LT1776 related to actual output current is composed of both DC and AC switching losses. These can be roughly estimated as follows: DC switching losses are dominated by output switch "ON voltage", i.e., PDC = VON * IOUT * DC VON = Output switch ON voltage, typically 1V at 500mA IOUT = Output current DC = ON duty cycle AC switching losses are typically dominated by power lost due to the finite rise time and fall time at the VSW node. Assuming, for simplicity, a linear ramp up of both voltage and current and a current rise/fall time equal to 15ns, 12 PAC = 1/2 * VIN * IOUT * (tr + tf + 30ns) * f tr = (VIN/1.6)ns in high dV/dt mode (VIN/0.16)ns in low dV/dt mode tf = (VIN/1.6)ns (irrespective of dV/dt mode) f = switching frequency Total power dissipation of the die is simply the sum of quiescent, DC and AC losses previously calculated. PD(TOTAL) = PQ + PDC + PAC Frequency Compensation Loop frequency compensation is performed by connecting a capacitor, or in most cases a series RC, from the output of the error amplifier (VC pin) to ground. Proper loop compensation may be obtained by empirical methods as described in detail in Application Note 19. Briefly, this involves applying a load transient and observing the dynamic response over the expected range of VIN and ILOAD values. As a practical matter, a second small capacitor, directly from the VC pin to ground is generally recommended to attenuate capacitive coupling from the VSW pin. A typical value for this capacitor is 100pF. (See Switch Node Considerations). Switch Node Considerations For maximum efficiency, switch rise and fall times are made as short as practical. To prevent radiation and high frequency resonance problems, proper layout of the components connected to the IC is essential, especially the power path. B field (magnetic) radiation is minimized by keeping output diode, switch pin and input bypass capacitor leads as short as possible. E field radiation is kept low by minimizing the length and area of all traces connected to the switch pin (VSW). A ground plane should always be used under the switcher circuitry to prevent interplane coupling. LT1776 U U W U APPLICATIONS INFORMATION The high speed switching current path is shown schematically in Figure 3. Minimum lead length in these paths is essential to ensure clean switching and minimal EMI. The paths containing the input capacitor, output switch and output diode are the only ones containing nanosecond rise and fall times. Keep these paths as short as possible. VIN + VIN C1 LT1776 VSW VOUT + D1 As an example, assume that the capacitance between the VSW node and a high impedance pin node is 0.1pF, and further assume that the high impedance node in question exhibits a capacitance of 1pF to ground. Due to the high dV/dt, large excursion behavior of the VSW node, this will couple a nearly 4V transient to the high impedance pin, causing abnormal operation. (This assumes the "typical" 40VIN to 5VOUT application.) An explicit 100pF capacitor added to the node will reduce the amplitude of the disturbance to more like 50mV (although settling time will increase). Specific pin recommendations are as follows: C2 1776 F03 SHDN: If unused, add a 100pF capacitor to ground. SYNC: Ground if unused. Figure 3. High Speed Current Switching Paths Additionally, it is possible for the LT1776 to cause EMI problems by "coupling to itself". Specifically, this can occur if the VSW pin is allowed to capacitively couple in an uncontrolled manner to the part's high impedance nodes, i.e., SHDN, SYNC, VC and FB. This can cause erratic operation such as odd/even cycle behavior, pulse width "nervousness", improper output voltage and/or premature current limit action. VC: Add a capacitor directly to ground in addition to the explicit compensation network. A value of one-tenth of the main compensation capacitor is recommended, up to a maximum of 100pF. FB: Assuming the VC pin is handled properly, this pin usually requires no explicit capacitor of its own, but keep this node physically small to minimize stray capacitance. 13 LT1776 U TYPICAL APPLICATIONS Minimum Component Count Application User-Programmable Undervoltage Lockout Figure 4a shows a basic "minimum component count" application. The circuit produces 5V at up to 500mA IOUT with input voltages in the range of 10V to 40V. The typical POUT/PIN efficiency is shown in Figure 4b. As shown, the SHDN and SYNC pins are unused, however either (or both) can be optionally driven by external signals as desired. Figure 5 adds a resistor divider to the basic application. This is a simple, cost-effective way to add a userprogrammable undervoltage lockout (UVLO) function. Resistor R5 is chosen to have approximately 200A through it at the nominal SHDN pin lockout threshold of 1.25V. The somewhat arbitrary value of 200A was VIN 10V TO 40V 5 1 + C1 39F 63V C5 100pF 6 VIN 2 SHDN VCC 3 VSW L1 D1 MBRS1100 100H LT1776 7 FB 8 VC SYNC C3 2200pF X7R R3 22k 5% GND 4 + C4 100pF C2 100F 10V R1 36.5k 1% R2 12.1k 1% 1776 F04a C1: PANASONIC HFQ C2: AVX D CASE TPSD107M010R0080 C4, C5: X7R OR COG/NPO D1: MOTOROLA 100V, 1A, SMD SCHOTTKY L1: COILCRAFT DO3316P-104 FOR 3.3V VOUT VERSION: R1: 24.3K, R2: 14.7k L1: 68H, DO3316P-683 IOUT: 0mA TO 500mA Figure 4a. Minimum Component Count Application 90 80 EFFICIENCY (%) 70 60 50 40 VIN = 10V 30 VIN = 20V VIN = 30V 20 1 VIN = 40V 10 100 1000 ILOAD (mA) 1776 F04b Figure 4b. POUT/PIN Efficiency 14 VOUT 5V 0mA to 500mA LT1776 U TYPICAL APPLICATIONS VIN R4 158k 1% + 5 C1 1 VIN SHDN VCC VSW 2 L1 3 LT1776 R5 6.19k 1% C5 6 FB SYNC VC GND 4 VOUT + D1 C2 R1 7 8 C3 C4 R2 R3 1776 F05 Figure 5. User Programmable Undervoltage Lockout chosen to be significantly above the SHDN pin input current to minimize its error contribution, but significantly below the typical 3.8mA the LT1776 draws in lockout mode. Resistor R4 is then chosen to yield this same 200A, less 2.5A, with the desired VIN UVLO voltage minus 1.25V applied across it. (The 2.5A factor is an allowance to minimize error due to SHDN pin input current.) Behavior is as follows: Normal operation is observed at the nominal input voltage of 40V. As the input voltage is decreased to roughly 32V, switching action will stop, VOUT will drop to zero, and the LT1776 will draw its VIN and VCC quiescent currents from the VIN supply. At a much lower input voltage, typically 14V or so at 25C, the voltage on the SHDN pin will drop to the shutdown threshold, and the part will draw its shutdown current only from the VIN rail. The resistive divider of R4 and R5 will continue to draw power from VIN. (The user should be aware that while the SHDN pin lockout threshold is relatively accurate including temperature effects, the SHDN pin shutdown threshold is more coarse, and exhibits considerably more temperature drift. Nevertheless the shutdown threshold will always be well below the lockout threshold.) Minimum Size Inductor Application Figure 4a employs power path parts that are capable of delivering the full rated output capability of the LT1776. Potential users with low output current requirements may be interested in substituting a physically smaller and less costly power inductor. The circuit shown in Figure 6a is topologically identical to the basic application, but specifies a much smaller inductor. This circuit is capable of delivering up to 400mA at 5V, or, up to 500mA at 3.3V. The only disadvantage is that due to the increased resistance in the inductor, the circuit is no longer capable of withstanding indefinite short circuits to ground. The LT1776 will still current limit at its nominal ILIM value, but this will overheat the inductor. Momentary short circuits of a few seconds or less can still be tolerated. Typical efficiency is shown in Figure 6b. 15 LT1776 U TYPICAL APPLICATIONS VIN 10V TO 40V 5 VIN 1 SHDN VCC VSW + C1 C5 2 3 D1 LT1776 6 + L1 68H R1 36.5k 1% C2 7 FB 8 VC SYNC C3 C4 R2 12.1k 1% R3 22k 5% GND 4 VOUT 5V 0mA to 400mA 1776 F06a C1: PANASONIC HFQ 39F AT 63V C2: AVX D CASE 100F 10V TPSD107M010R0080 C3: 2200pF, X7R C4, C5: 100pF, X7R OR COG/NPO D1: MOTOROLA 100V, 1A, SMD SCHOTTKY MBRS1100 (T3) L1: COILCRAFT DO1608C-683 FOR 3.3V VOUT VERSION: IOUT: 0mA TO 500mA L1: 47H, DO1608C-473 R1: 24.3K, R2: 14.7k (a) 90 80 EFFICIENCY (%) 70 60 50 40 VIN = 10V VIN = 20V 30 VIN = 30V 20 1 VIN = 40V 10 100 LOAD CURRENT (mA) 1000 1776 F06b (b) Figure 6. Minimum Inductor Size Application Burst Mode Operation Configuration Figure 4b demonstrates that power supply efficiency degrades with lower output load current. This is not surprising, as the LT1776 itself represents a fixed power overhead. A possible way to improve light load efficiency is in Burst Mode operation. Figure 7 shows the LT1776 configured for Burst Mode operation. Output voltage regulation is now provided in a 16 "bang-bang" digital manner, via comparator U2, an LTC1440. Resistor divider R3/R4 provides a scaled version of the output voltage, which is compared against U2's internal reference. Intentional hysteresis is set by the R5/ R6 divider. As the output voltage falls below the regulation range, the LT1776 is turned on. The output voltage rises, and as it climbs above the regulation range, the LT1776 is turned off. Efficiency is maximized, as the LT1776 is only powered up while it is providing heavy output current. LT1776 U TYPICAL APPLICATIONS VIN + 5 C1 6 R7 10M VIN VCC SYNC VSW 2 U1 LT1776 Q1 PN2484 1 + D1 C2 7 FB 8 VC SHDN GND Q2* 2N2369 L1 3 NC R3 323k 1% 7 8 V+ OUT 4 IN - 3 + IN U2 LTC1440 6 REF 5 HYST - V GND C1: PANASONIC HFQ 39F AT 63V C2: AVX D CASE 100F 10V TPSD107M010R0080 D1: MOTOROLA 100V, 1A, SMD SCHOTTKY MBRS1100 (T3) L1: COILCRAFT DO3316-104 *ANY NPN WITH EMITTER-BASE BREAKDOWN OF <7V CAN BE USED 2 1 R1 39k 5% R2 10k 5% C3 100pF 4 VOUT 5V R5 22k R4 100k 1% R6 2.4M 1776 F07a (a) 90 80 VIN = 10V EFFICIENCY (%) 70 VIN = 40V VIN = 30V VIN = 20V 60 50 40 30 20 1 10 100 LOAD CURRENT (mA) 1000 1776 F07b (b) Figure 7. Burst Mode Operation Configuration for High Efficiency at Light Load 17 LT1776 U TYPICAL APPLICATIONS Figure 7b shows that efficiency is typically maintained at 75% or better down to a load current of 10mA. Even at a load of 1mA, efficiency is still a respectable 58% to 68%, depending on VIN. Resistor divider R1/R2 is still present, but does not directly influence output voltage. It is chosen to ensure that the LT1776 delivers high output current throughout the voltage regulation range. Its presence is also required to maintain proper short-circuit protection. Transistors Q1, Q2 and resistor R7 form a high VIN, low quiescent current voltage regulator to power U2. Wide VIN Range, High Efficiency Battery Charger The circuit on the final page of this data sheet shows the LT1776 configured as a constant-current/constant-voltage battery charger. An LT1620 rail-to-rail, current sense amplifier (U2) monitors the differential voltage across current sense resistor R4. As this equals and exceeds the voltage set across resistor R5 in the R5/R6 divider, the LT1620 responds by sinking current at its IOUT pin. This is connected to the VC control node of the LT1776 and therefore acts to reduce the amount of power delivered to the load. The overall constant-current/constant-voltage behavior can be seen in the graph titled Battery Charger Output Voltage vs Output Current. Target voltage and current limits are independently programmable. Output voltage, presently 6V, is set by the R1/R2 divider and the internal reference of the LT1776. Output current, presently 200mA, is set by current sense resistor R4 and the R5-R6 divider. The circuit, as shown, accommodates an input voltage range of 10V to 30V. The accompanying graphs display efficiency for input voltages of 12V and 24V. The upper input voltage limit of 30V is determined not by the LT1776, but by the LT1121-5 regulator (U3). (A regulated 5V is required by the LT1620.) This regulator was chosen for its 18 micropower behavior, which helps maintain good overall efficiency. However, the basic catalog part is only rated to 30V. Substitution of the industry standard LM317, for example, extends the allowable input voltage to 40V (or more with the HV part), but its greater quiescent current drain degrades efficiency from that shown. A related concern in charger applications is the current drain seen at the battery when charger power is removed. Strictly speaking, this can occur in three separate ways: the VIN supply can go to zero (VIN = short circuit), the VIN supply can be disconnected (VIN = open circuit) or the SHDN function can be asserted. The worst-case is generally VIN = 0V, and this situation will be assumed. A diode is then required in the battery charger power path to prevent reverse current flow. There are three logical places for this diode. The first is directly in series with the VSW node. This has the advantage of smallest efficiency penalty, as the diode forward drop subtracts from the input voltage. A disadvantage is that the battery must still power the LT1776 VCC pin, yielding a current drain of several mA. In this position the diode is called upon to switch on and off rapidly, so a Schottky type, similar to that used as the freewheeling diode (D1), is recommended. Placing the diode between output filter capacitor C2 and feedback divider R1/R2 limits the current drain to only the current drawn by the feedback divider, perhaps 100A or so. However, the efficiency penalty is greater, as the diode forward drop is now in series with the output voltage. When absolute minimal battery drain is required, the diode may be placed between the R1/R2 feedback divider and the battery itself. This limits current drain to just the reverse leakage of the diode. In this case the feedback divider must be adjusted for the nominal forward drop of the diode. In either of these positions, a Schottky diode will offer the least efficiency penalty, but a standard silicon diode can be used in the most cost sensitive applications. LT1776 U PACKAGE DESCRIPTION Dimensions in inches (millimeters) unless otherwise noted. N8 Package 8-Lead PDIP (Narrow 0.300) (LTC DWG # 05-08-1510) 0.400* (10.160) MAX 8 7 6 5 1 2 3 4 0.255 0.015* (6.477 0.381) 0.300 - 0.325 (7.620 - 8.255) 0.065 (1.651) TYP 0.009 - 0.015 (0.229 - 0.381) ( +0.035 0.325 -0.015 8.255 +0.889 -0.381 0.130 0.005 (3.302 0.127) 0.045 - 0.065 (1.143 - 1.651) ) 0.125 (3.175) 0.020 MIN (0.508) MIN 0.018 0.003 (0.457 0.076) N8 1197 0.100 0.010 (2.540 0.254) *THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS. MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.010 INCH (0.254mm) S8 Package 8-Lead Plastic Small Outline (Narrow 0.150) (LTC DWG # 05-08-1610) 0.189 - 0.197* (4.801 - 5.004) 8 7 6 5 0.150 - 0.157** (3.810 - 3.988) 0.228 - 0.244 (5.791 - 6.197) 1 0.010 - 0.020 x 45 (0.254 - 0.508) 0.008 - 0.010 (0.203 - 0.254) 0.053 - 0.069 (1.346 - 1.752) 0- 8 TYP 0.016 - 0.050 0.406 - 1.270 0.014 - 0.019 (0.355 - 0.483) *DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE **DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE 2 3 4 0.004 - 0.010 (0.101 - 0.254) 0.050 (1.270) TYP SO8 0996 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. 19 LT1776 U TYPICAL APPLICATION Wide VIN Range, High Efficiency Battery Charger VIN 10V TO 30V (SEE TEXT) + 5 C1 39F 63V VIN 1 SHDN C5 100pF 7 FB 2 VCC U1 LT1776 3 VSW 6 8 SYNC VC L1 100H C4 2200pF C3 100pF GND C7 0.1F C8 1F + C6 0.33F D1 MBRS1100 BATTERY R2 12.1k 1% VCC 2 IOUT U2 LT1620 7 5 PROG IN + 4 1 - NC SENSE IN GND R6 12k C2 100F 10V R1 46.4k 1% 6 8 R5 3k + R3 22k 4 U3 LT1121-5 R4 0.5 AVG C1: PANASONIC HFQ C2: AVX TPSD107M010R0080 L1: COILCRAFT DO3316P-104 1776 TA02 3 Battery Charger Efficiency -- Constant VOUT Region Battery Charger Efficiency -- Constant IOUT Region 90 7 80 80 6 OUTPUT VOLTAGE (V) 90 70 70 VIN = 12V EFFICIENCY (%) EFFICIENCY (%) Battery Charger Output Voltage vs Output Current 60 VIN = 24V 50 VIN = 12V 60 VIN = 24V 50 40 40 30 30 10 100 LOAD CURRENT (mA) 1000 4 3 2 1 0 20 20 5 0 1 4 3 2 OUTPUT VOLTAGE (V) 5 6 0 50 100 150 200 OUTPUT CURRENT (mA) 1776 TA04 1776 TA03 250 1776 TA05 RELATED PARTS PART NUMBER DESCRIPTION COMMENTS LT1076 2A, 100kHz Step-Down Switching Regulator Operation Up to 45V Input (64V for HV Version) LTC 1149 High Efficiency Synchronous Step-Down Switching Regulator Operation Up to 48V Input, 95% Efficiency, 100% Duty Cycle LT1374 4.5A, 500kHz Step-Down Switching Regulator Converts 12V to 3.3V at 2.5A in SO-8 Package LT1375/LT1376 1.5A, 500kHz Step-Down Switching Regulators Operation Up to 25V Input, Synchronizable (LT1375) LT1620 Rail-to-Rail Current Sense Amplifier Transforms Switching Regulators into High Efficiency Battery Chargers LT1676 Wide Input Range, High Efficiency, Step-Down Switching Regulator 7.4V to 60V Input, 100kHz Operation, 700mA Internal Switch LT1777 Low Noise Buck Regulator Operation up to 48V, Controlled Voltage and Current Slew Rates (R) 20 Linear Technology Corporation 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408)432-1900 FAX: (408) 434-0507 www.linear-tech.com sn1776 1776fs LT/TP 0499 4K * PRINTED IN USA LINEAR TECHNOLOGY CORPORATION 1998