SNVSA13C Data sheet

SNVSA13C April 2014 – April 2019 LM46002

PRODUCTION DATA.

Package Options

Mechanical Data (Package|Pins)

PWP|16
- MPDS371A

Thermal pad, mechanical data (Package|Pins)

PWP|16
- PPTD297B

Orderable Information

8.2.3 Application Performance Curves

Please refer to Table 2 for bill of materials for each V_OUT and F_S combination. Unless otherwise stated, application performance curves were taken at T_A = 25 °C.

V_OUT = 3.3 V

F_S = 500 kHz

V_IN = 24 V

Figure 47. BOM for V_OUT = 3.3 V F_S = 500 kHz

LM46002 C007_voutr_3p3V_500kHz_snvsa13.png

V_OUT = 3.3 V

F_S = 500 kHz

Figure 49. Output Voltage Regulation

LM46002 tc06_loadtrans_3p3V_500k_snvsa13.gif

V_OUT = 3.3 V

F_S = 500 kHz

V_IN = 24 V

Figure 51. Load Transient Between 0.1 A and 2 A

V_OUT = 5 V

F_S = 500 kHz

V_IN = 24 V

Figure 53. BOM for V_OUT = 5 V F_S = 500 kHz

LM46002 C009_voutr_5V_500kHz_snvsa13.png

V_OUT = 5 V

F_S = 500 kHz

Figure 55. Output Voltage Regulation

LM46002 tc08_loadtrans_5V_500k_snvsa13.gif

V_OUT = 5 V

F_S = 500 kHz

V_IN = 24 V

Figure 57. Load Transient Between 0.1 A and 2 A

V_OUT = 5 V

F_S = 200 kHz

V_IN = 24 V

Figure 59. BOM for V_OUT = 5 V F_S = 200 kHz

LM46002 C008_voutr_5V_200kHz_snvsa13.png

V_OUT = 5 V

F_S = 200 kHz

Figure 61. Output Voltage Regulation

LM46002 tc07_loadtrans_5V_200k_snvsa13.gif

V_OUT = 5 V

F_S = 200 kHz

V_IN = 24 V

Figure 63. Load Transient Between 0.1 A and 2 A

V_OUT = 5 V

F_S = 1 MHz

V_IN = 24 V

Figure 65. BOM for V_OUT = 5 V F_S = 1 MHz

V_OUT = 5 V

F_S = 1 MHz

Figure 67. Output Voltage Regulation

LM46002 tc09_loadtrans_5V_1M_snvsa13.gif

V_OUT = 5 V

F_S = 1 MHz

V_IN = 24 V

Figure 69. Load Transient Between 0.1 A and 2 A

V_OUT = 12 V

F_S = 500 kHz

V_IN = 24 V

Figure 71. BOM for V_OUT = 12 V F_S = 500 kHz

LM46002 C011_voutr_12V_500kHz_snvsa13.png

V_OUT = 12 V

F_S = 500 kHz

Figure 73. Output Voltage Regulation

LM46002 tc10_loadtrans_12V_500k_snvsa13.gif

V_OUT = 12 V

F_S = 500 kHz

V_IN = 24 V

Figure 75. Load Transient Between 0.1 A and 2 A

V_OUT = 24 V

F_S = 500 kHz

V_IN = 48 V

Figure 77. BOM for V_OUT = 24 V F_S = 500 kHz

LM46002 C012_voutr_24V_500kHz_snvsa13.png

V_OUT = 24 V

F_S = 500 kHz

Figure 79. Output Voltage Regulation

LM46002 tc11_loadtrans_48V_to_24V_snvsa13.gif

V_OUT = 24 V

F_S = 500 kHz

V_IN = 48 V

Figure 81. Load Transient Between 0.1 A and 2 A

V_OUT = 3.3 V

F_S = 500 kHz

R_θJA = 20°C/W

Figure 83. Derating Curve with R_θJA = 20°C/W

V_OUT = 5 V

F_S = 200 kHz

R_θJA = 20°C/W

Figure 85. Derating Curve with R_θJA = 20°C/W

V_OUT = 3.3 V

F_S = 500 kHz

Figure 87. Switching Frequency vs I_OUT in PFM Operation

V_OUT = 3.3 V

F_S = 500 kHz

I_OUT = 2 A

Figure 89. Switching Waveform in CCM Operation

V_OUT = 3.3 V

F_S = 500 kHz

I_OUT = 5 mA

Figure 91. Switching Waveform in PFM Operation

LM46002 tc02_startup_3p3V_1A_snvsa13.gif

V_IN = 24 V

V_OUT = 3.3 V

R_LOAD = 3.3 Ω

Figure 93. Startup Into Half Load with Internal Soft-Start Rate

LM46002 tc04_prebias_3p3V_0A_snvsa13.gif

V_IN = 24 V

V_OUT = 3.3 V

R_LOAD = Open

Figure 95. Startup Into 1.5 V Pre-biased Voltage

LM46002 tc12_linetrans_12V_to_36V_2A_snvsa13.gif

V_OUT = 3.3 V

F_S = 500 kHz

I_OUT = 2 A

Figure 97. Line Transient: V_IN Transitions Between 12 V and 36 V, 1 V/µs Slew Rate

LM46002 tc14_shortcut_release_500k_snvsa13.gif

V_OUT = 3.3 V

F_S = 500 kHz

V_IN = 24 V

Figure 99. Short Circuit Protection and Recover

LM46002 C001_eff_3p3V_500kHz_snvsa13.png

V_OUT = 3.3 V

F_S = 500 kHz

Figure 48. Efficiency

LM46002 C013_dropo_3p3V_500kHz_snvsa13.png

V_OUT = 3.3 V

F_S = 500 kHz

Figure 50. Drop-Out Curve

V_OUT = 3.3 V

F_S = 500 kHz

V_IN = 24 V

Figure 52. Derating Curve

V_OUT = 5 V

F_S = 500 kHz

Figure 54. Efficiency

LM46002 C015_dropo_5V_500kHz_snvsa13.png

V_OUT = 5 V

F_S = 500 kHz

Figure 56. Dropout Curve

V_OUT = 5 V

F_S = 500 kHz

V_IN = 24 V

Figure 58. Derating Curve

V_OUT = 5 V

F_S = 200 kHz

Figure 60. Efficiency

LM46002 C014_dropo_5V_200kHz_snvsa13.png

V_OUT = 5 V

F_S = 200 kHz

Figure 62. Dropout Curve

V_OUT = 5 V

F_S = 200 kHz

Figure 64. Derating Curve

V_OUT = 5 V

F_S = 1 MHz

V_IN = 24 V

Figure 66. Efficiency

V_OUT = 5 V

F_S = 1 MHz

Figure 68. Dropout Curve

V_OUT = 5 V

F_S = 1 MHz

V_IN = 24 V

Figure 70. Derating Curve

V_OUT = 12 V

F_S = 500 kHz

Figure 72. Efficiency

LM46002 C017_dropo_12V_500kHz_snvsa13.png

V_OUT = 12 V

F_S = 500 kHz

Figure 74. Dropout Curve

V_OUT = 12 V

F_S = 500 kHz

V_IN = 24 V

Figure 76. Derating Curve

V_OUT = 24 V

F_S = 500 kHz

Figure 78. Efficiency

LM46002 C018_dropo_24V_500kHz_snvsa13.png

V_OUT = 24 V

F_S = 500 kHz

Figure 80. Dropout Curve

V_OUT = 24 V

F_S = 500 kHz

V_IN = 48 V

Figure 82. Derating Curve

V_OUT = 5 V

F_S = 500 kHz

R_θJA = 20°C/W

Figure 84. Derating Curve with R_θJA = 20°C/W

V_OUT = 5 V

F_S = 1 MHz

R_θJA = 20°C/W

Figure 86. Derating Curve with R_θJA = 20°C/W

V_OUT = 5 V

F_S = 1 MHz

Figure 88. Switching Frequency vs I_OUT in PFM Operation

V_OUT = 3.3 V

F_S = 500 kHz

I_OUT = 130 mA

Figure 90. Switching Waveform in DCM Operation

LM46002 tc01_startup_3p3V_2A_snvsa13.gif

V_IN = 24 V

V_OUT = 3.3 V

R_LOAD = 1.65 Ω

Figure 92. Startup Into Full Load with Internal Soft-Start Rate

LM46002 tc03_startup_3p3V_0p1A_snvsa13.gif

V_IN = 24 V

V_OUT = 3.3 V

R_LOAD = 33 Ω

Figure 94. Startup Into 100 mA with Internal Soft-Start Rate

V_IN = 24 V

V_OUT = 12 V

R_LOAD = 6 Ω

Figure 96. Startup with External Capacitor C_SS

LM46002 tc13_linetrans_12V_to_36V_0p5A_snvsa13.gif

V_OUT = 3.3 V

F_S = 500 kHz

I_OUT = 0.5 A

Figure 98. Line Transient: V_IN Transitions Between 12 V and 36 V, 1 V/µs Slew Rate