JAJSOZ4 データシート

JAJSOZ4A June 2023 – June 2024 TPS6521905

PRODUCTION DATA

パッケージ・オプション

メカニカル・データ（パッケージ｜ピン）

RSM|32
- MPQF195B
RHB|32
- MPQF130D

サーマルパッド・メカニカル・データ

RSM|32
- QFND112H
RHB|32
- QFND676

発注情報

5.7 BUCK2, BUCK3 Converter

over operating free-air temperature range (unless otherwise noted)

POS	PARAMETER		TEST CONDITIONS	MIN	TYP	MAX	UNIT
Electrical Characteristics
6.1.1a	V_{IN_BUCK23}	Input Voltage⁽¹⁾	Buck supply voltage, maximum VSYS	2.5		5.5	V
6.1.1b	V_{OUT_BUCK23}	Buck Output Voltage configurable Range	Output voltage configurable in 25mV-steps for 0.6V ≤ V_OUT ≤ 1.4V, in 100mV steps for 1.4V < V_OUT ≤ 3.4V	0.6		3.4	V
6.1.2a	I_{Q_BUCK23}	Quiescent Current at 25°C, PFM	PFM, BUCKx enabled, no load, V_IN = 5.0V, V_OUT = 1.2V, T_J=25°C		10	13	μA
6.1.2b	I_{Q_BUCK23}	Quiescent Current -40°C to 125°C, PFM, low BW case	PFM, BUCKx enabled, no load, V_IN = 5.0V, V_OUT = 1.2V, T_J=-40°C to 125°C		15	43	μA
6.1.2c	I_{Q_BUCK23}	Quiescent Current -40°C to 150°C, PFM, low BW case	PFM, BUCKx enabled, no load, V_IN = 5.0V, V_OUT = 1.2V, T_J=-40°C to 150°C		20	63	μA
6.1.3a	V_{HEADROOM_PWM}	Input to Output Voltage Headroom⁽²⁾	Corner cases at maximum load I_OUT = 65% of I_{OUT_MAX}	500			mV
6.1.3b	V_{HEADROOM_PWM}	Input to Output Voltage Headroom at I_OUT = I_{OUT_MAX}⁽²⁾	Corner cases at I_OUT = I_{OUT_MAX}	700			mV
6.1.4	V_{OUT_STEP_LOW}	Output voltage Steps Buck2 and Buck3	0.6V ≤ V_OUT ≤ 1.4V		25		mV
6.1.5	V_{OUT_STEP_HIGH}	Output voltage Steps Buck2, Buck3	1.5V ≤ V_OUT ≤ 3.4V		100		mV
6.1.6a	V_{OUT_ACC_DC_PWM}	DC Output Voltage Accuracy in forced PWM mode, low and high BW case	I_OUT = I_{OUT_MAX}, V_OUT ≥ 0.7V to 3.4V, V_IN - V_OUT > 700 mV forced PWM, low BW case	–1.5%		1.5%
6.1.6b	V_{OUT_ACC_DC_PWM}	DC Output Voltage Accuracy in forced PWM mode, low and high BW case	I_OUT = I_{OUT_MAX}, V_OUT = 0.6V to 0.7V, V_IN - V_OUT > 700 mV forced PWM, low BW case	–10		10	mV
6.1.6c	V_{OUT_ACC_DC_PFM}	DC Output Voltage Accuracy in auto-PFM mode, low and high BW case	I_OUT = 1mA, V_OUT = 0.6V to 3.4V, V_IN - V_OUT > 500 mV auto-PFM, low BW case	–3.0%		3.5%
6.1.9	R_{FB_INPUT}	Feedback input impedance	Converter enabled	2.3	3.75	5.0	MΩ
6.2.1a	V_{LOAD_REG_PWM}	DC Load Regulation, forced PWM, low BW case	V_IN = 5.0V, V_OUT = 1.2V, I_OUT = 0 to I_{OUT_MAX}, forced PWM, low BW case		0.1	0.16	%/A
6.2.2a	V_{LINE_REG}	DC Line Regulation, forced PWM, low BW case	V_IN = 3.3V to 5.5V, V_OUT = 1.2V, I_OUT = 1mA and I_{OUT_MAX} forced PWM, low BW case, C_OUT = 40μF		0.1	0.16	%/V
6.2.3a	V_{LOAD_TRANSIENT}	Load Transient, V_OUT=0.75V, auto-PFM, high BW case	V_IN = 5.0V, V_OUT = 0.75V, I_OUT = 100mA to 1100mAto 100mA, t_R = t_F = 500ns, auto-PFM, high BW case, C_OUT = 80μF	–27.5		27.5	mV
6.2.3b	V_{LOAD_TRANSIENT}	Load Transient, V_OUT=0.75V, forced PWM, high BW case	V_IN = 5.0V, V_OUT = 0.75V, I_OUT = 100mA to 1100mAto 100mA, t_R = t_F = 500ns, forced PWM, high BW case, C_OUT = 80 μF	–27.5		27.5	mV
6.2.4a	V_{LOAD_TRANSIENT}	Load Transient, V_OUT=1.8V, auto-PFM, low BW case	V_IN = 5.0V, V_OUT = 1.8V, I_OUT = 1mA to 1Ato 1mA, t_R = t_F = 1μs, auto-PFM, C_OUT = 40μF	-90		90	mV
6.2.4b	V_{LOAD_TRANSIENT}	Load Transient, V_OUT=1.8V, forced PWM, low BW case	V_IN = 5.0V, V_OUT = 1.8V, I_OUT = 1mA to 1Ato 1mA, t_R = t_F = 1μs, forced PWM, C_OUT = 40μF	-60		60	mV
6.2.5a	V_{LINE_TRANSIENT}	Line Transient, V_OUT=1.2V, forced PWM, low BW case	V_IN = 3.3V to 5.5V in 50μs, V_OUT = 1.2V, I_OUT = 1mA and I_{OUT_MAX}, forced PWM, low BW case, C_OUT = 40μF	–50		50	mV
6.2.6a	V_{RIPPLE_PP_PWM}	Forced PWM Mode, low BW case	V_IN = 5.0V, V_OUT = 2.5V, forced PWM, low BW case, C_OUT = 40uF, X5R, ESR = 10mOhm, L = 470nH, DCR = 50mΩ I_OUT = 1A		10	20	mV_PP
6.2.6b	V_{RIPPLE_PP_PFM}	Auto PFM Mode, low BW case	V_IN = 5.0V, V_OUT = 2.5V, auto PFM, low BW case, C_OUT = 40uF, X5R, ESR = 10mOhm, L = 470nH, DCR = 50mΩ I_OUT = 20mA		20	40	mV_PP
6.3.1	I_{OUT_MAX}	Maximum Operating Current				2.0	A
6.3.2	I_{CURRENT_LIMIT}	Peak Current Limit	V_IN = 2.5V to 5.5V	3.1	3.9	4.7	A
6.3.3	I_{REV_CUR_LIMIT}	Reverse Peak Current Limit	V_IN = 2.5V to 5.5V	–2.0	–1.5	–1.0	A
6.3.4a	R_{DSON_HS}	High Side MOSFET On Resistance, 5V-supply	Measured Pin to Pin, V_IN = 5V			110	mΩ
6.3.4b	R_{DSON_HS}	High Side MOSFET On Resistance, 3.3V-supply	Measured Pin to Pin, V_IN = 3.3V			135	mΩ
6.3.5a	R_{DSON_LS}	Low Side MOSFET On Resistance, 5V-supply	Measured Pin to Pin, V_IN = 5V			110	mΩ
6.3.5b	R_{DSON_LS}	Low Side MOSFET On Resistance, 3.3V-supply	Measured Pin to Pin, V_IN = 3.3V			130	mΩ
6.3.6	R_DISCHARGE	Output Discharge Resistance	Active only when converter is disabled	60	125	200	Ω
6.4.1	L_SW	Output Inductance	DCR = 50mΩ max	330	470	611	nH
6.4.2a	C_OUT	Output Capacitance in auto-PFM or forced PWM for low BW case	ESR = 10mΩ max	10		75	μF
6.4.3a	C_{OUT_HIGH_BW}	Output Capacitance in auto-PFM or forced PWM for high BW case	ESR = 10mΩ max	30		220	μF
Timing Requirements
6.5.1	t_RAMP	Ramp Time in quasi-fixed-frequency mode	Time from enable to 98% of target value, assuming no residual voltage	0.3		1.65	ms
6.5.2a	DVFS_SLOPE_ QFF	DVFS timing requirements in forced PWM, low BW case	Step-duration during DVFS voltage adjustments from 0.6V to 1.4V	2.9	3.2	3.5	mV/μs
Switching Characteristics
6.5.2c	DVFS_FALL	DVFS timing requirements in forced PWM, falling slope	Step-duration during DVFS voltage adjustments from 1.4V to 0.6V	0.45	0.53	0.61	mV/μs
6.6.1a	f_SW	Switching Frequency, forced PWM, high or low BW case	Forced PWM, V_IN = 3.3V to 5V, V_OUT = 0.8V to 1.8V, I_OUT = 1A to 1.8A		2.3		MHz

(1) PVIN_Bx must not exceed VSYS

(2) Refers to DC-regulation only. Transient response may require more headroom. With low headroom, the frequency variation increases for quasi-fixed frequency.