JAJSU28 データシート

JAJSU28 March 2023 DRV8329-Q1

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）

RGF|40
- MPQF173F

サーマルパッド・メカニカル・データ

RGF|40
- QFND710

発注情報

jajsu28_oa

6.5 Electrical Characteristics

4.5 V ≤ V_PVDD ≤ 60 V, –40°C ≤ T_J≤ 150°C (unless otherwise noted). Typical limits apply for T_A = 25°C, V_PVDD = 24 V

PARAMETER		TEST CONDITIONS	MIN	TYP	MAX	UNIT
POWER SUPPLIES (AVDD, PVDD, GVDD)
I_PVDDQ	PVDD sleep mode current	V_PVDD=24V, nSLEEP = 0, T_A = 25°C			1	µA
I_PVDDQ	PVDD sleep mode current	nSLEEP = LOW			2	µA
I_PVDDS	PVDD standby mode current	V_PVDD = 24 V; nSLEEP = HIGH, INHx = INLX = LOW, DRVOFF = HIGH		2	4	mA
I_PVDDS	PVDD standby mode current	nSLEEP = HIGH, INHx = INLX = LOW, DRVOFF = HIGH		3	5.5	mA
I_PVDD	PVDD active mode current	V_PVDD = 24 V, nSLEEP = HIGH, INHx = INLX = Switching@20kHz, No FETs connected		4	7	mA
		nSLEEP = HIGH, INHx = INLX = Switching@20kHz, No FETs connected		5	10	mA
		V_PVDD = 8 V, nSLEEP = HIGH, INHx = INLX = LOW, No FETs connected		5	10	mA
		V_PVDD = 24 V, nSLEEP = HIGH, INHx = INLX = LOW, No FETs connected		5	7	mA
IL_BSx	Bootstrap pin leakage current	V_BSTx = V_SHx= 60V, V_GVDD = 0V, nSLEEP = LOW	5	10	16	µA
IL_{BS_TRAN}	Bootstrap pin active mode transient leakage current	INLx = INHx = Switching@20kHz, No FETs connected	60	115	300	µA
IL_{BS_DC_SRC}	Bootstrap pin active mode leakage static source current	INHx = HIGH, INLx = LOW, INLy = INLz = HIGH, nSLEEP = HIGH, V_PVDD = V_SHX= V_GVDD= 12V, V_BSTx - V_SHx = 5V	135	200	280	µA
		INHx = HIGH, INLx = LOW, INLy = INLz = HIGH, nSLEEP = HIGH, V_PVDD = V_SHX= V_GVDD= 12V, V_BSTx - V_SHx = 7V	70	105	145	µA
		INHx = LOW, INLx = LOW, INLy = INLz = HIGH, nSLEEP = HIGH, V_PVDD = V_SHX= V_GVDD= 12V, V_BSTx - V_SHx = 5V	25	50	90	µA
		INHx = LOW, INLx = LOW, INLy = INLz = HIGH, nSLEEP = HIGH, V_PVDD = V_SHX= V_GVDD= 12V, V_BSTx - V_SHx = 7V	16	28	50	µA
IL_{BS_DC_SINK}	Bootstrap pin active mode leakage static sink current	INHx = LOW, INLx = LOW, INLy = INLz = HIGH, nSLEEP = HIGH, V_PVDD = V_SHX= V_GVDD= 12V, V_BSTx - V_SHx = 12V	10	40	90	µA
IL_{BS_DC_SINK}	Bootstrap pin active mode leakage static sink current	INHx = High, INLx = LOW, INLy = INLz = HIGH, nSLEEP = HIGH, V_PVDD = V_SHX= V_GVDD= 12V, V_BSTx - V_SHx = 12V	14	45	91	µA
IL_SHx	Source pin leakage current	INHx = INLx = LOW, V_BSTx- V_SHx = 15, V_SHx = 0 to 60V, nSLEEP = HIGH, DRVOFF = LOW	80	145	210	µA
		INHx = INLx = LOW, V_BSTx- V_SHx = 11, V_SHx = 0 to 60V, nSLEEP = HIGH, DRVOFF = LOW	15	20	30	µA
		INHx = High, INLx = LOW, V_BSTx- V_SHx = 15, V_SHx = 0 to 60V, nSLEEP = HIGH, DRVOFF = LOW	80	145	210	µA
		INHx = HIGH, INLx = LOW, V_BSTx- V_SHx = 11, V_SHx = 0 to 60V, nSLEEP = HIGH, DRVOFF = LOW	13	25	35	µA
t_WAKE	Turnon time (nSLEEP)	nSLEEP = HIGH to Active mode (Outputs Ready), DRVOFF = LOW, C_GVDD = 10 uF, C_BSTx = 1 uF		1	2	ms
		nSLEEP = High to Active mode (Outputs Ready). C_GVDD = 100 uF, C_AVDD = 10 uF, C_BSTx = 10 uF		10	15	ms
		V_PVDD = 12V, nSLEEP = HIGH to Active mode (Outputs Ready), DRVOFF = LOW, C_GVDD = 10 uF		1	2	ms
	Turnon time (DRVOFF)	DRVOFF = LOW to Active mode (Outputs Ready), nSLEEP = High		0.05	0.1	ms
t_SLEEP	Turnoff time	nSLEEP = LOW to Sleep mode			20	us
t_RST	Minimum Reset Pulse Time	nSLEEP = LOW period to reset faults	1		1.2	us
V_{GVDD_RT}	GVDD Gate driver regulator voltage (Room Temperature)	V_PVDD≥ 40 V, I_GS = 10 mA, T_J= 25°C	11.8	13	15	V
		22 V ≤V_PVDD≤ 40 V, I_GS = 30 mA, T_J= 25°C	11.8	13	15	V
		8 V ≤V_PVDD≤ 22 V, I_GS = 30 mA, T_J= 25°C	11.8	13	15	V
		6.75 V ≤V_PVDD≤ 8 V, I_GS = 10 mA, T_J= 25°C	11.8	13	14.5	V
		4.5 V ≤V_PVDD≤ 6.75 V, I_GS = 10 mA, T_J= 25°C	2*V_PVDD - 1		13.5	V
V_GVDD	GVDD Gate driver regulator voltage	V_PVDD≥ 40 V, I_GS = 10 mA	11.5		15.5	V
		22 V ≤V_PVDD≤ 40 V, I_GS = 30 mA	11.5		15.5	V
		8 V ≤V_PVDD≤ 22 V; I_GS = 30 mA	11.5		15.5	V
		6.75 V ≤V_PVDD≤ 8 V, I_GS = 10 mA	11.5		14.5	V
		4.5 V ≤V_PVDD≤ 6.75 V, I_GS = 10 mA	2*V_PVDD - 1.4		13.5	V
V_{AVDD_RT}	AVDD Analog regulator voltage (Room Temperature)	V_PVDD≥ 6 V, 0 mA ≤ I_AVDD ≤ 30 mA, T_J= 25°C	3.26	3.3	3.33	V
		V_PVDD≥ 6 V, 30 mA ≤ I_AVDD ≤ 80 mA, T_J= 25°C	3.2	3.3	3.4	V
		V_PVDD≤ 6 V, 0 mA ≤ I_AVDD ≤ 50 mA, T_J= 25°C	3.13	3.3	3.46	V
V_AVDD	AVDD Analog regulator voltage	V_PVDD≥ 6 V, 0 mA ≤ I_AVDD ≤ 80 mA	3.2	3.3	3.4	V
V_AVDD	AVDD Analog regulator voltage	V_PVDD≤ 6 V, 0 mA ≤ I_AVDD ≤ 50 mA	3.125	3.3	3.5	V
LOGIC-LEVEL INPUTS (DRVOFF, INHx, INLx, nSLEEP etc)
V_IL	Input logic low voltage	DRVOFF			0.8	V
V_IL	Input logic low voltage	INLx, INHx pins			0.8	V
V_IH	Input logic high voltage	DRVOFF	2.2			V
V_IH	Input logic high voltage	INLx, INHx pins	2.2			V
V_HYS	Input hysteresis	DRVOFF	200	400	650	mV
V_HYS	Input hysteresis	INLx, INHx pins	45	240	350	mV
I_IL	Input logic low current	V_PIN(Pin Voltage) = 0 V;	-1	0	1	µA
I_IH	Input logic high current	nSLEEP, V_PIN(Pin Voltage) = 65 V;	3	6.5	10	µA
		nSLEEP, V_PIN(Pin Voltage) = 5 V;	3	6	10	µA
		Other pins, V_PIN(Pin Voltage) = 5 V;	7	20	35	µA
R_{PD_DRVOFF}	Input pulldown resistance	DRVOFF To GND	100	200	300	kΩ
R_{PD_nSLEEP}	Input pulldown resistance	nSLEEP To GND	500	800	1500	kΩ
R_PD	Input pulldown resistance	All other pins To GND	150	250	350	kΩ
FOUR-LEVEL INPUTS (GAIN)
V_L1	Input level 1 voltage	Tied to GND	0		0.18*AVDD	V
V_L2	Input level 2 voltage	50 kΩ +/- 5% tied to GND	0.48*AVDD	0.5*AVDD	0.52*AVDD	V
V_L3	Input level 3 voltage	200 kΩ +/- 5% tied to GND	0.82*AVDD	0.833*AVDD	0.85*AVDD	V
V_L4	Input level 4 voltage	HiZ or Connect to AVDD		AVDD		V
R_PU	Input pullup resistance	GAIN To AVDD	80	100	120	kΩ
OPEN-DRAIN OUTPUTS (nFAULT etc)
V_OL	Output logic low voltage	I_OD = 5 mA			0.4	V
I_OZ	Output logic high current	V_OD = 5 V	-1		1	µA
C_OD	Output capacitance	V_OD = 5 V			30	pF
GATE DRIVERS (GHx, GLx, SHx, SLx)
V_{GSHx_LO}	High-side gate drive low level voltage	I_GLx = -100 mA; V_GVDD= 12V; No FETs connected	0.05	0.11	0.24	V
V_{GSHx_HI}	High-side gate drive high level voltage (V_BSTx- V_GHx)	I_GHx = 100 mA; V_GVDD= 12V; No FETs connected	0.28	0.44	0.82	V
V_{GSLx_LO}	Low-side gate drive low level voltage	I_GLx = -100 mA; V_GVDD= 12V; No FETs connected	0.05	0.11	0.27	V
V_{GSLx_HI}	Low-side gate drive high level voltage (V_GVDD- V_GHx)	I_GHx = 100 mA; V_GVDD= 12V; No FETs connected	0.28	0.44	0.82	V
V_{GSH_100_PH}	High-side gate drive voltage in steady state with 100 % duty cycle (GHx- SHx)	INHx = HIGH, INLx = LOW, INLy = INLz = HIGH, V_PVDD>15V, V_GVDD ≥11.5V	8.4	9.6	11.1	V
		INHx = HIGH, INLx = LOW, INLy = INLz = HIGH, V_GVDD ≥11.5V	7.5	8.3	9	V
		INHx = HIGH, INLx = LOW, INLy = INLz = HIGH, 7V ≥V_GVDD ≥ 8V	5.7	6.5	7.6	V
R_{DS(ON)_PU_HS}	High-side pullup switch resistance	I_GHx = 100 mA; V_GVDD= 12V	2.7	4.5	8.4	Ω
R_{DS(ON)_PD_HS}	High-side pulldown switch resistance	I_GHx = 100 mA; V_GVDD= 12V	0.2	1.1	2.4	Ω
R_{DS(ON)_PU_LS}	Low-side pullup switch resistance	I_GLx = 100 mA; V_GVDD= 12V	2.7	4.5	8.3	Ω
R_{DS(ON)_PD_LS}	Low-side pulldown switch resistance	I_GLx = 100 mA; V_GVDD= 12V	0.2	1.1	2.8	Ω
I_{DRIVEP_HS}	High-side peak source gate current	V_GSHx = 12V	550	1000	1575	mA
I_{DRIVEN_HS}	High-side peak sink gate current	V_GSHx = 0V	1150	2000	2675	mA
I_{DRIVEP_LS}	Low-side peak source gate current	V_GSLx= 12V	550	1000	1575	mA
I_{DRIVEN_LS}	Low-side peak sink gate current	V_GSLx = 0V	1150	2000	2675	mA
R_{PD_LS}	Low-side passive pull down	GLx to LSS	80	100	120	kΩ
R_{PDSA_HS}	High-side semiactive pull down	GHx to SHx, V_GSHx = 2V	8	10	12.5	kΩ
GATE DRIVERS TIMINGS
t_{PDR_LS}	Low-side rising propagation delay	INLx to GLx rising, V_GVDD> 8V	70	100	145	ns
t_{PDF_LS}	Low-side falling propagation delay	INLx to GLx falling, V_GVDD> 8V	70	100	135	ns
t_{PDR_HS}	High-side rising propagation delay	INHx to GHx rising, V_GVDD = V_BSTx - V_SHx> 8V	65	100	145	ns
t_{PDF_HS}	High-side falling propagation delay	INHx to GHx falling, V_GVDD= V_BSTx - V_SHx> 8V	70	100	140	ns
t_{PD_MATCH_PH}	Matching propagation delay per phase	GLx turning ON to GLx turning OFF, V_GVDD= V_BSTx - V_SHx> 8V; SHx = 0V to 60V, No load on GHx and GLx	-25	±4	25	ns
		GLx turning OFF to GHx turning ON, V_GVDD= V_BSTx - V_SHx> 8V; SHx = 0V to 60V, No load on GHx and GLx	-28	±4	28	ns
		GHx turning ON to GHx turning OFF, V_GVDD= V_BSTx - V_SHx> 8V; SHx = 0V to 60V, No load on GHx and GLx	-25	±4	25	ns
		GHx turning OFF to GLx turning ON, V_GVDD= V_BSTx - V_SHx> 8V; SHx = 0V to 60V, No load on GHx and GLx	-25	±4	25	ns
t_{PD_MATCH_PH_PH}	Matching propagation delay phase to phase	GHx turning ON to GHy turning ON, V_GVDD= V_BSTx - V_SHx> 8V; SHx = 0V to 60V, No load on GHx and GLx	-10	±4	10	ns
		GLx turning ON to GLy turning ON, V_GVDD= V_BSTx - V_SHx> 8V; SHx = 0V to 60V, No load on GHx and GLx	-10	±4	10	ns
		GHx turning OFF to GHy turning OFF, V_GVDD= V_BSTx - V_SHx> 8V; SHx = 0V to 60V, No load on GHx and GLx	-15	±4	15	ns
		GLx turning OFF to GLy turning OFF, V_GVDD= V_BSTx - V_SHx> 8V; SHx = 0V to 60V, No load on GHx and GLx	-10	±4	10	ns
t_{PW_MIN}	Minimum input pulse width on INHx, INLx that changes the output on GHx, GLx		18	32	45	ns
t_DEAD	Gate drive dead time configurable range		50		2000	ns
t_DEAD	Gate drive dead time	DT pin floating	35	55	90	ns
		DT pin connected to GND	25	55	80	ns
		10 kΩ between DT pin and GND	75	100	140	ns
		390 kΩ between DT pin and GND	1350	2000	2650	ns
BOOTSTRAP DIODES
V_BOOTD	Bootstrap diode forward voltage	I_BOOT= 100 µA			0.8	V
V_BOOTD	Bootstrap diode forward voltage	I_BOOT= 100 mA			1.6	V
R_BOOTD	Bootstrap dynamic resistance (ΔV_BOOTD/ΔI_BOOT)	I_BOOT= 100 mA and 50 mA	4.5	5.5	9	Ω
CURRENT SHUNT AMPLIFIERS (SNx, SOx, SPx, CSAREF)
A_CSA	Sense amplifier gain	CSAGAIN = Tied to GND	4.92	5	5.05	V/V
		CSAGAIN = 50kΩ ±5% tied to GND	9.9	10	10.1	V/V
		CSAGAIN = 200kΩ ±5% tied to GND	19.75	20	20.2	V/V
		CSAGAIN =Hi-Z;	39.6	40	40.6	V/V
A_{CSA_ERR}	Sense amplifier gain error	T_J= 25℃	-1.5		1.5	%
A_{CSA_ERR_DRIFT}	Sense amplifier gain error temperature drift		-20		20	ppm/℃
NL	Non linearity Error			0.01	0.05	%
t_SET	Settling time to ±1%	V_STEP = 1.6 V, A_CSA = 5 V/V, C_LOAD = 500pF		0.6	1	µs
		V_STEP = 1.6 V, A_CSA = 10 V/V, C_LOAD = 500pF		0.6	1.1	µs
		V_STEP = 1.6 V, A_CSA = 20 V/V, C_LOAD = 500pF		0.7	1.2	µs
		V_STEP = 1.6 V, A_CSA = 40 V/V, C_LOAD = 500pF		0.8	1.7	µs
t_SET	Settling time to ±1%	V_STEP = 1.6 V, A_CSA = 5 V/V, C_LOAD = 60pF		0.3	0.5	µs
		V_STEP = 1.6 V, A_CSA = 10 V/V, C_LOAD = 60pF		0.3	0.5	µs
		V_STEP = 1.6 V, A_CSA = 20 V/V, C_LOAD = 60pF		0.3	0.65	µs
		V_STEP = 1.6 V, A_CSA = 40 V/V, C_LOAD = 60pF		0.3	0.8	µs
BW	Bandwidth	A_CSA = 5 V/V, C_LOAD = 60-pF, small signal -3 dB	3	5	7	MHz
		A_CSA = 10 V/V, C_LOAD = 60-pF, small signal -3 dB	2.5	4.8	6.6	MHz
		A_CSA = 20 V/V, C_LOAD = 60-pF, small signal -3 dB	2	4	5.4	MHz
		A_CSA = 40 V/V, C_LOAD = 60-pF, small signal -3 dB	1.75	3	4.2	MHz
t_SR	Output slew rate	V_STEP = 1.6 V, A_CSA = 5 V/V, C_LOAD = 60-pF, low to high transition		12		V/µs
		V_STEP = 1.6 V, A_CSA = 10 V/V, C_LOAD = 60-pF, low to high transition		13		V/µs
		V_STEP = 1.6 V, A_CSA = 20 V/V, C_LOAD = 60-pF, low to high transition		11		V/µs
		V_STEP = 1.6 V, A_CSA = 40 V/V, C_LOAD = 60-pF, low to high transition		11		V/µs
V_SWING	Output voltage range	V_CSAREF = 3	0.25		2.75	V
V_SWING	Output voltage range	V_CSAREF = 5.5	0.25		5.25	V
V_SWING	Output voltage range	V_CSAREF = 3 to 5.5 V	0.25		V_CSAREF- 0.25	V
V_COM	Common-mode input range		-0.15		0.15	V
V_DIFF	Differential-mode input range		-0.3		0.3	V
V_OFF	Input offset voltage	V_SP = V_SN = GND; T_J= -40℃, CSA_VREF = 0	-2.0		2.0	mV
V_OFF	Input offset voltage	V_SP = V_SN = GND; T_J= 25℃, CSA_VREF = 0	-1.9		1.9	mV
V_OFF	Input offset voltage	V_SP = V_SN = GND; T_J= 175℃, CSA_VREF= 0	-2.0		2.0	mV
V_OFF	Input offset voltage	V_SP = V_SN = GND	-2.0		2.0	mV
V_{OFF_DRIFT}	Input drift offset voltage	V_SP = V_SN = GND		8		µV/℃
V_BIAS	Output voltage bias ratio	V_SP = V_SN = GND	0.122	0.125	0.128	V
V_{BIAS_ACC}	Output voltage bias ratio accuracy	V_SP = V_SN = GND	-1.2		1.2	%
I_BIAS	Input bias current	V_SP = V_SN = GND, V_CSAREF = 3V to 5.5V			100	µA
I_{BIAS_OFF}	Input bias current offset	I_SP – I_SN	-1		1	µA
I_CSASRC	SO ouput sink current capability		5	7	11	mA
I_CSASRC	SO ouput source current capability		2	3.7	6.6	mA
CMRR	Common-mode rejection ratio	DC		80		dB
CMRR	Common-mode rejection ratio	20 kHz		65		dB
PSRR	Power-supply rejection ratio (CSAREF)	CSAREF to SOx, DC, Differential		80		dB
PSRR	Power-supply rejection ratio (CSAREF)	CSAREF to SOx, 20 kHz, Differential		70		dB
PSRR	Power-supply rejection ratio (CSAREF)	CSAREF to SOx, 20 kHz, Single Ended		40		dB
I_{CSA_SUP}	Supply current for CSA	V_CSAREF = 3.V to 5.5V		1.5	2.1	mA
T_CMREC	Common mode recovery time			0.6	0.7	us
C_LOAD	Maximum load capacitance			10		nF
V_{OFF_OUT}	Output offset error	A_CSA = 5 V/V	-3		3	mV
		A_CSA = 10 V/V	-4		4	mV
		A_CSA = 20 V/V	-5		5	mV
		A_CSA = 40 V/V	-6		6	mV
PROTECTION CIRCUITS
V_{PVDD_UV}	PVDD undervoltage lockout threshold	V_PVDD rising	4.3	4.4	4.5	V
V_{PVDD_UV}	PVDD undervoltage lockout threshold	V_PVDD falling	4	4.1	4.25	V
V_{PVDD_UV_HYS}	PVDD undervoltagelockout hysteresis	Rising to falling threshold	225	265	325	mV
t_{PVDD_UV_DG}	PVDD undervoltage deglitch time		10	20	30	µs
V_{AVDD_POR}	AVDD supply POR threshold	AVDD rising	2.7	2.85	3.0	V
V_{AVDD_POR}	AVDD supply POR threshold	AVDD falling	2.5	2.65	2.8	V
V_{AVDD_POR_HYS}	AVDD POR hysteresis	Rising to falling threshold	170	200	250	mV
t_{AVDD_POR_DG}	AVDD POR deglitch time		7	12	22	µs
V_{GVDD_UV}	GVDD undervoltage threshold	V_GVDD rising	7.3	7.5	7.8	V
V_{GVDD_UV}	GVDD undervoltage threshold	V_GVDD falling	6.4	6.7	6.9	V
V_{GVDD_UV_HYS}	GVDD undervoltage hysteresis	Rising to falling threshold	800	900	1000	mV
t_{GVDD_UV_DG}	GVDD undervoltage deglitch time		5	10	15	µs
V_{BST_UV}	Bootstrap undervoltage threshold	V_BSTx- V_SHx; V_BSTx rising	3.9	4.45	5	V
V_{BST_UV}	Bootstrap undervoltage threshold	V_BSTx- V_SHx; V_BSTx falling	3.7	4.2	4.8	V
V_{BST_UV_HYS}	Bootstrap undervoltage hysteresis	Rising to falling threshold	150	220	285	mV
t_{BST_UV_DG}	Bootstrap undervoltage deglitch time		2	4	6	µs
V_{DS_LVL_RNG}	V_DS overcurrent protection threshold linear range		0.1		2.5	V
V_{DS_DIS}	V_DS overcurrent protection disable resistor	VDSLVL pin to GVDD	70	100	500	kΩ
V_{DS_LVL}	V_DS overcurrent protection threshold Reference	VDSLVL = 100 kΩ to GVDD	3	4.2	5.5	V
		VDSLVL = 0.1V	0.065	0.1	0.145	V
		VDSLVL pin = 2.5V	2.2	2.5	2.8	V
V_{SENSE_LVL}	V_SENSE overcurrent protection threshold	LSS to GND pin = 0.5V	0.48	0.5	0.52	V
t_{DS_BLK}	V_DS overcurrent protection blanking time		0.5	1	2.7	µs
t_{DS_DG}	V_DS and V_SENSEovercurrent protection deglitch time		1.5	3	5	µs
t_{SD_SINK_DIG}	DRVOFF peak sink current duration		3	5	7	µs
t_{SD_DIG}	DRVOFF digital shutdown delay		0.5	1.5	2.2	µs
t_SD	DRVOFF analog shutdown delay		7	14	21	µs
T_OTSD	Thermal shutdown temperature	T_J rising;	160	170	187	°C
T_HYS	Thermal shutdown hysteresis		16	20	23	°C