米6体育平台手机版

SLUSFA1 September 2024 TPS1214-Q1

ADVANCE INFORMATION

封装选项

机械数据 (封装 | 引脚)

RGE|23
- MPQF802

散热焊盘机械数据 (封装 | 引脚)

订购信息

slusfa1_oa

9.3.2 External Component Selection

By following similar design procedure as outlined in Section 8.2.2, the external component values are calculated as below:

R_SNS = 0.5mΩ
R_SET = 300Ω
R_IMON = 18.2kΩ
R_IOC = 23kΩ to set 40A as I²t protection start threshold
C_I2t = 1µF to set 3000A²s as I²T factor
C_BST = 150nF
R_ISCP = 2.55kΩ to set 130A as short-circuit protection threshold
C_TMR = 47nF to set 1000ms auto-retry time
R3 and R4 are selected as 470kΩ and 107kΩ respectively to set VIN undervoltage lockout threshold at 6.5V

Programming the Load Wakeup Threshold, R_BYPASS and Q₃ Selection

During normal operation, the series resistor R_BYPASS is used to set load wakeup current threshold. After V_{G_GOOD} threshold is reached, the voltage between CS2+ and CS2– is compared against V_(LWU) threshold (200mV typ) for load wakeup event. For selecting the MOSFET Q3, important electrical parameters are the maximum continuous drain current I_D, the maximum drain-to-source voltage V_DS(MAX), the maximum drain-to-source voltage V_GS(MAX), and the drain-to-source ON resistance R_DSON.

Based on the design requirements, BUK7J1R4-40H is selected and its ratings are:

40V V_DS(MAX) and ±20V V_GS(MAX)

R_DS(ON) is 1.06mΩ typical at 10V VGS

R_BYPASS resistor value can be selected using below equation:

Equation 30.

R_{B Y P A S S} = \frac{V_{(L W U)}}{I_{L W U}}

To set 200mA load wakeup current, R_BYPASS resistor is calculated to be 1Ω.

The average power rating of the bypass resistor can be calculated by following equation:

Equation 31.

P_{A V G} = {I_{L W U}}^{2} \times R_{BY PA SS}

The average power dissipation of R_BYPASS is calculated to be 0.04W.

The peak power dissipation in the bypass resistor is given by following equation:

Equation 32.

P_{P E A K} = \frac{{V_{B A T T_M A X}}^{2}}{R_{BY PA SS}}

The peak power dissipation of R_BYPASS is calculated to be ~256W. The peak power dissipation time for power-up with short into LPM can be derived from t_{(LPM_SC)} parameter (5μs) in electrical characteristics table.

Based on P_PEAK and t_{(LPM_SC)}, 1Ω, 1%, 3/4W CRCW12101R00FKEAHP resistor is used to support both average and peak power dissipation for > t_{(LPM_SC)} time. TI suggests the designer to share the entire power dissipation profile of bypass resistor with the resistor manufacturer and get their recommendation.

The peak short-circuit current in bypass path can be calculated based on following equation:

Equation 33.

I_{P E A K_B Y P A S S} = \frac{V_{B A T T_M A X}}{R_{BY PA SS}}

I_{PEAK_BYPASS} is calculated to be 16A based on R_BYPASS selected in Equation 30. TI suggest the designer to ensure that operating point (V_{BATT_MAX}, I_{PEAK_BYPASS}) for bypass path (Q3) is within the SOA curve for > t_{(LPM_SC)} time.

Programming the Inrush Current, R_g and C_g Selection

Use following equation to calculate the I_INRUSH:

Equation 34.

I_{I N R U S H} = C_{L O A D} \times \frac{V_{B A T T_MAX}}{T_{c h a r g e}}

I_INRUSH calculated in Equation 34 should be always less than wakeup in short in low power mode (I_{LPM_SC}) current which can be calculated using following equation:

Equation 35.

I_{L P M_S C} = \frac{2 V}{R_{BY P ASS}}

For 1Ω R_BYPASS, I_{LPM_SC} is calculated to be 2A which is less than I_INRUSH.

Use following equation to calculate the required C_g based on I_INRUSH calculated in Equation 34.

Equation 36.

C_{g} = \frac{C_{L O A D} \times I_{(G)}}{I_{I N R U S H}}

Where, I_(G) is 100µA (typical)

To set I_INRUSH at 1.6A, C_g value is calculated to be ~50nF.

A series resistor R_g must be used in conjunction with Cg to limit the discharge current from Cg during turn-off .

The chosen value of R_g is 100Ω and C_g is 68nF.