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ZHCSP77A December 2021 – March 2022 TPS92624-Q1

PRODUCTION DATA

封裝選項

機械數據 (封裝 | 引腳)

PWP|20
- MHTS001H

散熱焊盤機械數據 (封裝 | 引腳)

PWP|20
- PPTD410

訂購信息

zhcsp77a_oa

6.6 Timing Requirements

		MIN	NOM	MAX	UNIT
t_{(PWM_delay_rising)}	PWM rising edge delay, V_IH(PWM) voltage to 10% of output current closed loop when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 0.665 ? and R_(RESx) = 56 ?, t₁ as shown in Figure 7-1		3	6	μs
	PWM rising edge delay, V_IH(PWM) voltage to 10% of output current closed loop when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 1 ? and R_(RESx) = 110 ?, t₁ as shown in Figure 7-1		3	6	μs
	PWM rising edge delay, V_IH(PWM) voltage to 10% of output current closed loop when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 10 ? and R_(RESx) = 27 ?, t₁ as shown in Figure 7-1		3	6	μs
t_{(PWM_delay_falling)}	PWM falling edge delay, V_IL(PWM) voltage to 90% of output current open loop when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 0.665 ? and R_(RESx) = 56 ?, t₃ as shown in Figure 7-1	1.2	2.4	3.6	μs
	PWM falling edge delay, V_IL(PWM) voltage to 90% of output current open loop when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 1 ? and R_(RESx) = 110 ?, t₃ as shown in Figure 7-1	1.6	2.6	4.2	μs
	PWM falling edge delay, V_IL(PWM) voltage to 90% of output current open loop when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 10 ? and R_(RESx) = 27 ?, t₃ as shown in Figure 7-1	1.6	2.6	4.2	μs
t_{(Current_rising)}	Output current rising from 10% to 90% when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 0.665 ? and R_(RESx) = 56 ?, t₂ as shown in Figure 7-1		2	5	μs
	Output current rising from 10% to 90% when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 1 ? and R_(RESx) = 110 ?, t₂ as shown in Figure 7-1		3	6	μs
	Output current rising from 10% to 90% when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 10 ? and R_(RESx) = 27 ?, t₂ as shown in Figure 7-1		3	6	μs
t_{(Current_falling)}	Output current falling from 90% to 10% when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 0.665 ? and R_(RESx) = 56 ?, t₄ as shown in Figure 7-1		5	7	μs
	Output current falling from 90% to 10% when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 50 mV, R_(SNSx) = 1 ? and R_(RESx) = 110 ?, t₄ as shown in Figure 7-1		1	2	μs
	Output current falling from 90% to 10% when V_(SUPPLY) = 12 V, V_(OUT) = 6 V, V_{(CS_REG)} = 50 mV, R_(SNSx) = 10 ? and R_(RESx) = 27 ?, t₄ as shown in Figure 7-1		1	2	μs
t_(STARTUP)	SUPPLY rising edge to 10% output current when C_(IREF) = C_(ICTRL)= 10 pF, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 0.665 ? and R_(RESx) = 56 ?, t₅ as shown in Figure 7-1		55	100	μs
	SUPPLY rising edge to 10% output current when C_(IREF) = C_(ICTRL)= 10 pF, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 10 ? and R_(RESx) = 110 ?, t₅ as shown in Figure 7-1		55	100	μs
	SUPPLY rising edge to 10% output current when C_(IREF) = C_(ICTRL)= 10 pF, V_(OUT) = 6 V, V_{(CS_REG)} = 100 mV, R_(SNSx) = 1 ? and R_(RESx) = 27 ?, t₅ as shown in Figure 7-1		55	100	μs
t_{(OPEN_deg)}	LED-open fault-deglitch time, t₆ as shown in Figure 7-4	75	125	199	μs
t_{(SG_deg)}	Output short-to-ground detection deglitch time, t₇ as shown in Figure 7-3	75	125	199	μs
t_{(Recover_deg)}	Open and Short fault recovery deglitch time, t₈ as shown in Figure 7-4 and Figure 7-3	75	125	199	μs
t_{(FAULT_deg)}	Fault pin digital deglitch time	7	10	13	μs
t_{(FAULT_recovery)}	Fault recovery delay time, t₉ as shown in Figure 7-4 and Figure 7-3	30	50	84	μs
t_{(TSD_deg)}	Thermal over temperature deglitch time	30	50	84	μs