9.1.1 Input Undervoltage Lockout (UVLO)

Undervoltage lockout is set with a resistor divider from V_IN to GND and is compared against a 1.24V threshold as shown in Figure 28. Once the input voltage is above the preset UVLO rising threshold (and assuming the part is enabled), the internal circuitry becomes active and a 22µA current source at the UVLO pin is turned on. This extra current provides hysteresis to create a lower UVLO falling threshold. The resistor divider is chosen to set both the UVLO rising and falling thresholds.

Figure 28. UVLO Circuit

The turn-on threshold (V_TURN-ON) is defined as follows:

Equation 17.

The hysteresis (V_HYS) is defined as follows:

Equation 18.

9.1.2 Operation Near Dropout

Because the power MOSFET is a PFET, the LM3409/09HV can be operated into dropout which occurs when the input voltage is approximately equal to output voltage. Once the input voltage drops below the nominal output voltage, the switch remains constantly on (D=1) causing the output voltage to decrease with the input voltage. In normal operation, the average LED current is regulated to the peak current threshold minus half of the ripple. As the converter goes into dropout, the LED current is exactly at the peak current threshold because it is no longer switching. This causes the LED current to increase by half of the set ripple current as it makes the transition into dropout. Therefore, the inductor current ripple should be kept as small as possible (while remaining above the previously established minimum) and output capacitance should be added to help maintain good line regulation when approaching dropout.

9.1.3 LED Ripple Current

Selection of the ripple current through the LED array is analogous to the selection of output ripple voltage in a standard voltage regulator. Where the output voltage ripple in a voltage regulator is commonly ±1% to ±5% of the DC output voltage, LED manufacturers generally recommend values for Δi_LED-PP ranging from ±5% to ±20% of I_LED. For a nominal system operating point, a larger Δi_LED-PP specification can reduce the necessary inductor size and/or allow for smaller output capacitors (or no output capacitors at all) which helps to minimize the total solution size and cost. On the other hand, a smaller Δi_LED-PP specification would require more output inductance, a higher switching frequency, or additional output capacitance.

9.1.4 Buck Converters without Output Capacitors

Because current is being regulated, not voltage, a buck current regulator is free of load current transients, therefore output capacitance is not needed to supply the load and maintain output voltage. This is very helpful when high frequency PWM dimming the LED load. When no output capacitor is used, the same design equations that govern Δi_L-PP also apply to Δi_LED-PP.

9.1.5 Buck Converters With Output Capacitors

A capacitor placed in parallel with the LED load can be used to reduce Δi_LED-PP while keeping the same average current through both the inductor and the LED array. With an output capacitor, the inductance can be lowered, making the magnetics smaller and less expensive. Alternatively, the circuit can be run at lower frequency with the same inductor value, improving the efficiency and increasing the maximum allowable average output voltage. A parallel output capacitor is also useful in applications where the inductor or input voltage tolerance is poor. Adding a capacitor that reduces Δi_LED-PP to well below the target provides headroom for changes in inductance or V_IN that might otherwise push the maximum Δi_LED-PP too high.

Figure 29. Calculating Dynamic Resistance r_D

Output capacitance (C_O) is determined knowing the desired Δi_LED-PP and the LED dynamic resistance (r_D). r_D can be calculated as the slope of the LED’s exponential DC characteristic at the nominal operating point as shown in Figure 29. Simply dividing the forward voltage by the forward current at the nominal operating point will give an incorrect value that is 5x to 10x too high. Total dynamic resistance for a string of n LEDs connected in series can be calculated as the r_D of one device multiplied by n. The following equations can then be used to estimate Δi_LED-PP when using a parallel capacitor:

Equation 19.

Equation 20.

In general, Z_C should be at least half of r_D to effectively reduce the ripple. Ceramic capacitors are the best choice for the output capacitors due to their high ripple current rating, low ESR, low cost, and small size compared to other types. When selecting a ceramic capacitor, special attention must be paid to the operating conditions of the application. Ceramic capacitors can lose one-half or more of their capacitance at their rated DC voltage bias and also lose capacitance with extremes in temperature. Make sure to check any recommended de-ratings and also verify if there is any significant change in capacitance at the operating voltage and temperature.

9.1.6 Output Overvoltage Protection

Because the LM3409/09HV controls a buck current regulator, there is no inherent need to provide output overvoltage protection. If the LED load is opened, the output voltage will only rise as high as the input voltage plus any ringing due to the parasitic inductance and capacitance present at the output node. If a ceramic output capacitor is used in the application, it should have a minimum rating equal to the input voltage. Ringing seen at the output node should not damage most ceramic capacitors, due to their high ripple current rating.

9.1.7 Input Capacitors

Input capacitors are selected using requirements for minimum capacitance and RMS ripple current. The PFET current during t_ON is approximately I_LED, therefore the input capacitors discharge the difference between I_LED and the average input current (I_IN) during t_ON. During t_OFF, the input voltage source charges up the input capacitors with I_IN. The minimum input capacitance (C_IN-MIN) is selected using the maximum input voltage ripple (Δv_IN-MAX) which can be tolerated. Δv_IN-MAX is equal to the change in voltage across C_IN during t_ON when it supplies the load current. A good starting point for selection of C_IN is to use Δv_IN-MAX of 2% to 10% of V_IN. C_IN-MIN can be selected as follows:

Equation 21.

An input capacitance at least 75% greater than the calculated C_IN-MIN value is recommended. To determine the RMS input current rating (I_IN-RMS) the following approximation can be used:

Equation 22.

Because this approximation assumes there is no inductor ripple current, the value should be increased by 10-30% depending on the amount of ripple that is expected. Ceramic capacitors are the best choice for input capacitors for the same reasons mentioned in the Buck Converters With Output Capacitors section. Careful selection of the capacitor requires checking capacitance ratings at the nominal operating voltage and temperature.

9.1.8 P-Channel MOSFET (PFET)

The LM3409/09HV requires an external PFET (Q1) as the main power MOSFET for the switching regulator. Q1 should have a voltage rating at least 15% higher than the maximum input voltage to ensure safe operation during the ringing of the switch node. In practice all switching converters have some ringing at the switch node due to the diode parasitic capacitance and the lead inductance. The PFET should also have a current rating at least 10% higher than the average transistor current (I_T):

Equation 23.

The power rating is verified by calculating the power loss (P_T) using the RMS transistor current (I_T-RMS) and the PFET on-resistance (R_DS-ON):

Equation 24.

Equation 25.

It is important to consider the gate charge of Q1. As the input voltage increases from a nominal voltage to its maximum input voltage, the COFT architecture will naturally increase the switching frequency. The dominant switching losses are determined by input voltage, switching frequency, and PFET total gate charge (Q_g). The LM3409/09HV must provide and remove charge Q_g from the input capacitance of Q1 to turn it on and off. This occurs more often at higher switching frequencies which requires more current from the internal regulator, thereby increasing internal power dissipation and eventually causing the LM3409/09HV to thermally cycle. For a given range of operating points the only effective way to reduce these switching losses is to minimize Q_g.

A good rule of thumb is to limit Q_g < 30nC (if the switching frequency remains below 300kHz for the entire operating range then a larger Q_g can be considered). If a PFET with small R_DS-ON and a high voltage rating is required, there may be no choice but to use a PFET with Q_g > 30nC.

When using a PFET with Q_g > 30nC, the bypass capacitor (C_F) should not be connected to the VIN pin. This will ensure that peak current detection through R_SNS is not affected by the charging of the PFET input capacitance during switching, which can cause false triggering of the peak detection comparator. Instead, C_F should be connected from the VCC pin to the CSN pin which will cause a small DC offset in V_CST and ultimately I_LED, however it avoids the problematic false triggering.

In general, the PFET should be chosen to meet the Q_g specification whenever possible, while minimizing R_DS-ON. This will minimize power losses while ensuring the part functions correctly over the full operating range.

9.1.9 Re-Circulating Diode

A re-circulating diode (D1) is required to carry the inductor current during t_OFF. The most efficient choice for D1 is a Schottky diode due to low forward voltage drop and near-zero reverse recovery time. Similar to Q1, D1 must have a voltage rating at least 15% higher than the maximum input voltage to ensure safe operation during the ringing of the switch node and a current rating at least 10% higher than the average diode current (I_D):

Equation 26.

The power rating is verified by calculating the power loss through the diode. This is accomplished by checking the typical diode forward voltage (V_D) from the I-V curve on the product data sheet and calculating as follows:

Equation 27.

In general, higher current diodes have a lower V_D and come in better performing packages minimizing both power losses and temperature rise.

9.2.1 EN PIN PWM Dimming Application for 10 LEDs

Figure 30. EN PIN PWM Dimming Application for 10 LEDs Schematic

9.2.1.2 Detailed Design Procedure

Table 1. Design 1 Bill of Materials

QTY	PART ID	PART VALUE	MANUFACTURER	PART NUMBER
1	LM3409HV/LM3409QHV	Buck controller	TI	LM3409HVMY/LM3409QHVMY
2	CIN1, CIN2	2 µF X7R 10% 100 V	MURATA	GRM43ER72A225KA01L
1	CF	1 µF X7R 10% 16 V	TDK	C1608X7R1C105K
1	COFF	470 pF X7R 10% 50 V	TDK	C1608X7R1H471K
1	Q1	PMOS 100 V 3.8 A	ZETEX	ZXMP10A18KTC
1	D1	Schottky 100 V 3 A	VISHAY	SS3H10-E3/57T
1	L1	15 µH 20% 4.2 A	TDK	SLF12565T-150M4R2
1	ROFF	24.9 kΩ 1%	VISHAY	CRCW060324K9FKEA
1	RUV1	6.98 kΩ 1%	VISHAY	CRCW06036K98FKEA
1	RUV2	49.9 kΩ 1%	VISHAY	CRCW060349K9FKEA
1	RSNS	0.1 Ω 1% 1W	VISHAY	WSL2512R1000FEA

9.2.1.2.1 Nominal Switching Frequency

Assume C_OFF = 470 pF and η = 0.95. Solve for R_OFF:

Equation 28.

The closest 1% tolerance resistor is 24.9 kΩ; therefore, the actual t_OFF and target f_SW are:

Equation 29.

Equation 30.

The chosen components from step 1 are:

Equation 31.

9.2.1.2.2 Inductor Ripple Current

Solve for L1:

Equation 32.

The closest standard inductor value is 15 µH therefore the actual Δi_L-PP is:

Equation 33.

The chosen component from step 2 is:

Equation 34.

9.2.1.2.3 Average LED Current

Determine I_L-MAX:

Equation 35.

Assume V_ADJ = 1.24 V and solve for R_SNS:

Equation 36.

The closest 1% tolerance resistor is 0.1 Ω therefore the I_LED is:

Equation 37.

The chosen component from step 3 is:

Equation 38.

9.2.1.2.4 Output Capacitance

No output capacitance is necessary.

9.2.1.2.5 Input Capacitance

Determine t_ON:

Equation 39.

Solve for C_IN-MIN:

Equation 40.

Choose C_IN:

Equation 41.

Determine I_IN-RMS:

Equation 42.

The chosen components from step 5 are:

Equation 43.

9.2.1.2.6 PFET

Determine minimum Q1 voltage rating and current rating:

Equation 44.

Equation 45.

A 100 V, 3.8 A PFET is chosen with R_DS-ON = 19 0mΩ and Q_g = 20 nC. Determine I_T-RMS and P_T:

Equation 46.

Equation 47.

The chosen component from step 6 is:

Equation 48.

9.2.1.2.7 Diode

Determine minimum D1 voltage rating and current rating:

Equation 49.

Equation 50.

A 100-V, 3-A diode is chosen with V_D = 750 mV. Determine P_D:

Equation 51.

The chosen component from step 7 is:

Equation 52.

9.2.1.2.8 Input UVLO

Solve for R_UV2:

Equation 53.

The closest 1% tolerance resistor is 49.9 kΩ therefore V_HYS is:

Equation 54.

Solve for R_UV1:

Equation 55.

The closest 1% tolerance resistor is 6.98 kΩ therefore V_TURN-ON is:

Equation 56.

The chosen components from step 8 are:

Equation 57.

9.2.1.2.9 IADJ Connection Method

The IADJ pin is left open forcing V_ADJ = 1.24 V.

9.2.1.2.10 PWM Dimming Method

PWM dimming signal pair is applied to the EN pin and GND at f_DIM = 1 kHz.

9.2.1.3 Application Curve

Figure 31 shows the LED current versus EN pin PWM duty cycle for the application.

Black = 200 Hz

Red = 1 kHz

Gray = 20 kHz

Figure 31. EN Pin PWM Dimming

9.2.2 Analog Dimming Application for 4 LEDs

9.2.2.2 Detailed Design Procedure

Table 2. Design 2 Bill of Materials

QTY	PART ID	PART VALUE	MANUFACTURER	PART NUMBER
1	LM3409/LM3409Q	Buck controller	TI	LM3409MY/LM3409QMY
2	CIN1	4.7-µF X7R 10% 50 V	MURATA	GRM55ER71H475MA01L
1	CF	1-µF X7R 10% 16 V	TDK	C1608X7R1C105K
1	CF2	0.1-µF X7R 10% 16 V	TDK	C1608X7R1C104K
1	COFF	470-pF X7R 10% 50 V	TDK	C1608X7R1H471K
1	CO	2.2-µF X7R 10% 50 V	MURATA	GRM43ER71H225MA01L
1	Q1	PMOS 70 V 5.7 A	ZETEX	ZXMP7A17KTC
1	D1	Schottky 60 V 5 A	COMCHIP	CDBC560-G
1	L1	22 µH 20% 4.2 A	TDK	SLF12575T-220M4R0
1	RF2	1 kΩ 1%	VISHAY	CRCW06031K00FKEA
1	ROFF	15.4 kΩ 1%	VISHAY	CRCW060315K4FKEA
1	RUV1	6.98 kΩ 1%	VISHAY	CRCW06036K98FKEA
1	RUV2	49.9 kΩ 1%	VISHAY	CRCW060349K9FKEA
1	RSNS	0.2 Ω 1% 1W	VISHAY	WSL2512R2000FEA

9.2.2.2.1 Nominal Switching Frequency

Assume C_OFF = 470 pF and η = 0.90. Solve for R_OFF:

Equation 58.

The closest 1% tolerance resistor is 15.4 kΩ; therefore, the actual t_OFF and target f_SW are:

Equation 59.

Equation 60.

The chosen components from step 1 are:

Equation 61.

9.2.2.2.2 Inductor Ripple Current

Solve for L1:

Equation 62.

The closest standard inductor value is 22 µH; therefore, the actual Δi_L-PP is:

Equation 63.

The chosen component from step 2 is:

Equation 64.

9.2.2.2.3 Average LED Current

Determine I_L-MAX:

Equation 65.

Assume V_ADJ = 1.24 V and solve for R_SNS:

Equation 66.

The closest 1% tolerance resistor is 0.2 Ω therefore I_LED is:

Equation 67.

The chosen component from step 3 is:

Equation 68.

9.2.2.2.4 Output Capacitance

Assume r_D = 2 Ω and determine Z_C:

Equation 69.

Solve for C_O-MIN and :

Equation 70.

Choose C_O:

Equation 71.

The chosen component from step 5 is:

Equation 72.

9.2.2.2.5 Input Capacitance

Determine t_ON:

Equation 73.

Solve for C_IN-MIN:

Equation 74.

Choose C_IN:

Equation 75.

Determine I_IN-RMS:

Equation 76.

The chosen component from step 5 is:

Equation 77.

9.2.2.2.6 PFET

Determine minimum Q1 voltage rating and current rating:

Equation 78.

Equation 79.

A 70V, 5.7 A PFET is chosen with R_DS-ON = 190 mΩ and Q_g = 20 nC. Determine I_T-RMS and P_T:

Equation 80.

Equation 81.

The chosen component from step 6 is:

Equation 82.

9.2.2.2.7 Diode

Determine minimum D1 voltage rating and current rating:

Equation 83.

Equation 84.

A 60 V, 5 A diode is chosen with V_D = 750 mV. Determine P_D:

Equation 85.

The chosen component from step 7 is:

Equation 86.

9.2.2.2.8 Input UVLO

Solve for R_UV2:

Equation 87.

The closest 1% tolerance resistor is 49.9 kΩ therefore V_HYS is:

Equation 88.

Solve for R_UV1:

Equation 89.

The closest 1% tolerance resistor is 6.98 kΩ therefore V_TURN-ON is:

Equation 90.

The chosen components from step 8 are:

Equation 91.

9.2.2.2.9 IADJ Connection Method

The IADJ pin is connected to an external voltage source and varied from 0 – 1.24 V to dim. An RC filter (R_F2 = 1 kΩ and C_F2 = 0.1 µF) is used as recommended.

9.2.2.2.10 PWM Dimming Method

No PWM dimming is necessary.

9.2.2.3 Application Curve

Figure 32 shows the LED current versus IADJ voltage for the application.

Figure 32. Analog Dimming Profile

9.2.3 LM3409 Buck Converter Application

Figure 33. LM3409 Buck Converter Simplified Schematic

9.2.3.2 Detailed Design Procedure

9.2.3.2.1 Nominal Switching Frequency

Calculate switching frequency (f_SW) at the nominal operating point (V_IN and V_O). Assume a C_OFF value (from 470 pF to 1 nF) and a system efficiency (η). Solve for R_OFF:

Equation 92.

9.2.3.2.2 Inductor Ripple Current

Set the inductor ripple current (Δi_L-PP) by solving for the appropriate inductor (L1):

Equation 93.

9.2.3.2.3 Average LED Current

Set the average LED current (I_LED) by first solving for the peak inductor current (I_L-MAX):

Equation 94.

Peak inductor current is detected across the sense resistor (R_SNS). In most cases, assume the maximum value (V_ADJ = 1.24 V) at the IADJ pin and solve for R_SNS:

Equation 95.

If the calculated R_SNS is far from a standard value, the beginning of the process can be iterated to choose a new R_OFF, L1, and R_SNS value that is a closer fit. The easiest way to approach the iterative process is to change the nominal f_SW target knowing that the switching frequency varies with operating conditions anyways.

Another method for finding a standard R_SNS value is to change the V_ADJ value. However, this would require an external voltage source or a resistor from the IADJ pin to GND as explained in the Adjustable Peak Current Control section of this data sheet.

9.2.3.2.4 Output Capacitance

A minimum output capacitance (C_O-MIN) may be necessary to reduce Δi_LED-PP below Δi_L-PP. With the specified Δi_LED-PP and the known dynamic resistance (r_D) of the LED string, solve for the required impedance (Z_C) for C_O-MIN:

Equation 96.

Solve for C_O-MIN:

Equation 97.

9.2.3.2.5 Input Capacitance

Set the input voltage ripple (Δv_IN-PP) by solving for the required minimum capacitance (C_IN-MIN):

Equation 98.

The necessary RMS input current rating (I_IN-RMS) is:

Equation 99.

9.2.3.2.6 PFET

The PFET voltage rating should be at least 15% higher than the maximum input voltage (V_IN-MAX) and current rating should be at least 10% higher than the average PFET current (I_T):

Equation 100.

Given a PFET with on-resistance (R_DS-ON), solve for the RMS transistor current (I_T-RMS) and power dissipation (P_T):

Equation 101.

Equation 102.

9.2.3.2.7 Diode

The Schottky diode needs a voltage rating similar to the PFET. Higher current diodes with a lower forward voltage are suggested. Given a diode with forward voltage (V_D), solve for the average diode current (I_D) and power dissipation (P_D):

Equation 103.

Equation 104.

9.2.3.2.8 Input UVLO

Input UVLO is set with the turnon threshold voltage (V_TURN-ON) and the desired hysteresis (V_HYS). To set V_HYS, solve for R_UV2:

Equation 105.

To set V_TURN-ON, solve for R_UV1:

Equation 106.

9.2.3.2.9 IADJ Connection Method

The IADJ pin controls the high-side current sense threshold in three ways outlined in the Adjustable Peak Current Control section.

Method 1: Leave IADJ pin open and I_LED is calculated as in the Average LED Current section of the Design Guide.

Method 2: Apply an external voltage (V_ADJ) to the IADJ pin from 0 to 1.24 V to analog dim or to reduce I_LED as follows:

Equation 107.

Keep in mind that analog dimming will eventually push the converter in to DCM and the inductor current ripple will no longer be constant causing a divergence from linear dimming at low levels.

A 0.1 µF capacitor connected from the IADJ pin to GND is recommended when using this method. It may also be necessary to have a 1kΩ series resistor with the capacitor to create an RC filter. The filter will help remove high frequency noise created by other connected circuitry.

Method 3: Connect an external resistor or potentiometer to GND (R_EXT) and the internal 5 µA current source will set the voltage. Again, a 0.1 µF capacitor connected from the IADJ pin to GND is recommended. To set I_LED, solve for R_EXT:

Equation 108.

9.2.3.2.10 PWM Dimming Method

There are two methods to PWM dim using the LM3409/09HV:

Method 1:Apply an external PWM signal to the EN terminal.

Method 2: Perform external parallel FET shunt dimming as detailed in the External Parallel FET PWM Dimming section.