国产精品久久久爽爽爽麻豆色哟哟,欧美大杂交18P,精品国产

ZHCSQR8A March 2023 – December 2023 TMAG5170D-Q1

PRODUCTION DATA

封裝選項

機械數據 (封裝 | 引腳)

PW|16
- MPDS361B

散熱焊盤機械數據 (封裝 | 引腳)

訂購信息

5.5 Electrical Characteristics

Over T_A = –40°C to 125°C range and V_CC = 2.3 V to 5.5 V (unless otherwise noted); Typical specification are at T_A = 25°C and V_CC = 5 V (unless otherwise noted)

PARAMETER		TEST CONDITIONS	MIN	TYP	MAX	UNIT
Digital Input/Output
V_IH	Input logic high voltage, SDI1, CS1, SCK1, SDI2, CS2, SCK2		0.75 * V_CC			V
V_IL	Input logic low voltage, SDI1, CS1, SCK1, ALERT1, SDI2, CS2, SCK2, ALERT2				0.25 * V_CC	V
V_OH	Output HIGH voltage, SDOx pins	I_OUT = 2 mA	V_CC–0.4		V_CC	V
V_OL	Output LOW voltage, SDOx pins	I_OUT = -2 mA	0		0.4	V
V_OL	Output LOW voltage, ALERTx pins	I_OUT = -2 mA	0		0.4	V
t_{FALL_ALERT}	ALERTx output fall time	R_PU = 10 k? C_L = 20 pF		50		ns
t_ALERT	ALERTx output pulse width with conversion complete or threshold cross interrupt event	ALERT_MODE = 0h Interrupt & Trigger Mode		5		μs
t_ALERT	ALERTx output pulse width with other interrupt events	ALERT_MODE = 0h Interrupt & Trigger Mode		31		μs
I_OZ	Output Leakage current, ALERTx pins	ALERT pin disabled V_OZ = 5.5 V	0	30	100	nA
Power Supply
V_{CC_PORRise}	Power on reset voltage at VCCx ramping up		1.15	1.4	1.7	V
V_{CC_PORFall}	Power off reset voltage at VCCx ramping down		0.8	1.2	1.6	V
V_{CC_UV}	Under voltage threshold at VCCx		2.0	2.1	2.3	V
V_{CC_OV}	Over voltage threshold at VCCx		5.57	5.9	6.9	V
I_ACTIVE	Active mode current from VCC1 or VCC2	CS high		3.4	4.5	mA
I_STDBY	Stand-by mode current from VCC1 or VCC2	CS high		0.8	1.2	mA
I_CFG	Configuration mode current from VCC1 or VCC2	CS high		0.06	0.15	mA
I_SLP	Sleep mode current from VCC1 or VCC2	CS high		1.3	45	μA
I_{DEEP_SLP}	Deep sleep mode current from VCC1 or VCC2	CS high		5	300	nA
I_{CC_DCM}	Duty-cycle mode current consumption for each die One channel enabled CONV_AVG = 0h	Data active rate 1000 Hz		290		μA
		Data active rate 100 Hz		34		μA
		Data active rate 10 Hz		4.5		μA
		Data active rate 1 Hz		2.2		μA
	Duty-cycle mode current consumption for each die Two channels enabled CONV_AVG = 0h	Data active rate 1000 Hz		360		μA
		Data active rate 100 Hz		43		μA
		Data active rate 10 Hz		5		μA
		Data active rate 1 Hz		2.3		μA
Operating Speed
t_{w_trigger}	Pulse width for conversion trigger input signal			15		μs
t_measure	Conversion time ⁽¹⁾ OPERATING_MODE = 2h One channel enabled	CONV_AVG = 0h⁽²⁾		50		μs
t_measure	Conversion time ⁽¹⁾ OPERATING_MODE = 2h One channel enabled	CONV_AVG = 5h⁽³⁾		825		μs
f_HFOSC	Internal high-frequency oscillator speed		2.95	3.2	3.5	MHz
f_LFOSC	Internal low-frequency oscillator speed		13.5	16	19.5	KHz
Temperature Sensing
T_{SENS_T0}	Reference temperature for TADC_T0		20.5	25	29.5	℃
TADC_T0	TEMP_RESULT decimal value @ T_{SENS_T0}			17522
TADC_RES	Temp sensing resolution		58.2	60.0	61.8	LSB/℃
NRMS (T)	RMS (1 Sigma) temperature noise	CONV_AVG = 5h		0.06		℃
NRMS (T)	RMS (1 Sigma) temperature noise	CONV_AVG = 0h		0.35		℃
Sensor Location
d_{s1_s2}	Sensor displacement in the X and Y plane			25	75	μm
A_{s1_s2}	Relative angular rotation between top and bottom sensor in degree			1	3	deg

(1) To calculate the time between conversion request and the availability of the conversion result, add the initialization time to the t_measure as explained in Comparing Operating Modes Table. For continuous conversion, the initialization time is applicable only for the first conversion.

(2) Add 25 μs for each additional channel enabled for conversion with CONV_AVG = 0h.

(3) For conversion with CONV_AVG = 5h, each axis data is collected 32 times. If an additional channel is enabled with CONV_AVG = 5h, add 32×25 μs = 80 0μs to the t_measureto calculate the conversion time for two axes.