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ZHCSO45 October 2021 TCAN1044AEV-Q1

PRODUCTION DATA

封裝選項(xiàng)

機(jī)械數(shù)據(jù) (封裝 | 引腳)

D|8
- MSOI002K
DDF|8
- MPDS569D

散熱焊盤機(jī)械數(shù)據(jù) (封裝 | 引腳)

訂購(gòu)信息

zhcso45_oa

6.8 Electrical Characteristics

Over recommended operating conditions with T_A = -40℃ to 150℃ (unless otherwise noted)

PARAMETER			TEST CONDITIONS	MIN	TYP	MAX	UNIT
Driver Electrical Characteristics
V_O(DOM)	Dominant output voltage Normal mode	CANH	STB = 0 V, TXD = 0 V 50 ? ≤ R_L ≤ 65 ?, C_L = open, R_CM = open See Figure 7-2 and Figure 8-3	2.75		4.5	V
V_O(DOM)	Dominant output voltage Normal mode	CANL		0.5		2.25	V
V_O(REC)	Recessive output voltage Normal mode	CANH and CANL	STB = 0 V, TXD = V_IO R_L = open (no load), R_CM = open See Figure 7-2 and Figure 8-3	2	0.5 V_CC	3	V
V_SYM	Driver symmetry (V_O(CANH) + V_O(CANL))/V_CC		STB = 0 V, TXD = 250 kHz, 1 MHz, 2.5 MHz R_L= 60 ?, C_SPLIT = 4.7 nF, C_L = open, R_CM = open See Figure 7-2 and Figure 9-2	0.9		1.1	V/V
V_{SYM_DC}	DC output symmetry (V_CC - V_O(CANH) - V_O(CANL))		STB = 0 V R_L= 60 ?, C_L = open See Figure 7-2 and Figure 8-3	–400		400	mV
V_OD(DOM)	Differential output voltage Normal mode Dominant	CANH - CANL	STB = 0 V, TXD = 0 V 50 ? ≤ R_L ≤ 65 ?, C_L = open See Figure 7-2 and Figure 8-3	1.5		3	V
			STB = 0 V, TXD = 0 V 45 ? ≤ R_L ≤ 70 ?, C_L = open See Figure 7-2 and Figure 8-3	1.4		3.3	V
			STB = 0 V, TXD = 0 V R_L = 2240 ?, C_L = open See Figure 7-2 and Figure 8-3	1.5		5	V
V_OD(REC)	Differential output voltage Normal mode Recessive	CANH - CANL	STB = 0 V, TXD = V_IO R_L = 60 ?, C_L = open See Figure 7-2 and Figure 8-3	–120		12	mV
V_OD(REC)	Differential output voltage Normal mode Recessive	CANH - CANL	STB = 0 V, TXD = V_IO R_L = open, C_L = open See Figure 7-2 and Figure 8-3	–50		50	mV
V_O(STB)	Bus output voltage Standby mode	CANH	STB = V_IO R_L = open See Figure 7-2 and Figure 8-3	-0.1		0.1	V
		CANL		-0.1		0.1	V
		CANH - CANL		-0.2		0.2	V
I_{OS(SS_DOM)}	Short-circuit steady-state output current, dominant Normal mode		STB = 0 V, TXD = 0 V V_(CANH) = -15 V to 40 V, CANL = open See Figure 7-7 and Figure 8-3	–115			mA
I_{OS(SS_DOM)}			STB = 0 V, TXD = 0 V V_{(CAN_L)} = -15 V to 40 V, CANH = open See Figure 7-7 and Figure 8-3			115	mA
I_{OS(SS_REC)}	Short-circuit steady-state output current, recessive Normal mode		STB = 0 V, TXD = V_IO –27 V ≤ V_BUS ≤ 32 V, where V_BUS = CANH = CANL See Figure 7-7 and Figure 8-3	–5		5	mA
Receiver Electrical Characteristics
V_IT	Input threshold voltage Normal mode		STB = 0 V -12 V ≤ V_CM ≤ 12 V See Figure 7-3 and Table 8-5	500		900	mV
V_IT(STB)	Input threshold Standby mode		STB = V_IO -12 V ≤ V_CM ≤ 12 V See Figure 7-3 and Table 8-5	400		1150	mV
V_DOM	Dominant state differential input voltage range Normal mode		STB = 0 V -12 V ≤ V_CM ≤ 12 V See Figure 7-3 and Table 8-5	0.9		9	V
V_REC	Recessive state differential input voltage range Normal mode		STB = 0 V -12 V ≤ V_CM ≤ 12 V See Figure 7-3 and Table 8-5	-4		0.5	V
V_DOM(STB)	Dominant state differential input voltage range Standby mode		STB = V_IO -12 V ≤ V_CM ≤ 12 V See Figure 7-3 and Table 8-5	1.15		9	V
V_REC(STB)	Recessive state differential input voltage range Standby mode		STB = V_IO -12 V ≤ V_CM ≤ 12 V See Figure 7-3 and Table 8-5	-4		0.4	V
V_HYS	Hysteresis voltage for input threshold Normal mode		STB = 0 V -12 V ≤ V_CM ≤ 12 V See Figure 7-3 and Table 8-5		115		mV
V_CM	Common-mode range Normal and standby modes		See Figure 7-3 and Table 8-5	–12		12	V
I_LKG(IOFF)	Unpowered bus input leakage current		CANH = CANL = 5 V, V_CC = V_IO = GND			5	μA
C_I	Input capacitance to ground (CANH or CANL)		TXD = V_IO			20	pF
C_ID	Differential input capacitance		TXD = V_IO			10	pF
R_ID	Differential input resistance		STB = 0 V, TXD = V_IO -12 V ≤ V_CM ≤ 12 V	40		90	kΩ
R_IN	Single-ended input resistance (CANH or CANL)		STB = 0 V, TXD = V_IO -12 V ≤ V_CM ≤ 12 V	20		45	kΩ
R_IN(M)	Input resistance matching [1 – (R_IN(CANH) / R_IN(CANL))] × 100 %		V_{(CAN_H)} = V_{(CAN_L)}= 5 V	–1		1	%
TXD Terminal (CAN Transmit Data Input)
V_IH	High-level input voltage			0.7 V_IO			V
V_IL	Low-level input voltage					0.3 V_IO	V
I_IH	High-level input leakage current		TXD = V_CC = V_IO = 5.5 V	–2.5	0	1	μA
I_IL	Low-level input leakage current		TXD = 0 V V_CC= V_IO = 5.5 V	–200	-100	–20	μA
I_LKG(OFF)	Unpowered leakage current		TXD = 5.5 V V_CC= V_IO = 0 V	–1	0	1	μA
C_I	Input capacitance		V_IN = 0.4×sin(2×π×2×10⁶×t)+2.5 V		5		pF
RXD Terminal (CAN Receive Data Output)
V_OH	High-level output voltage		I_O = –1.5 mA See Figure 7-3	0.8 V_IO			V
V_OL	Low-level output voltage		I_O = 1.5mA See Figure 7-3			0.2 V_IO	V
I_LKG(OFF)	Unpowered leakage current		RXD = 5.5 V V_CC = V_IO = 0 V	–1	0	1	μA
STB Terminal (Standby Mode Input)
V_IH	High-level input voltage			0.7 V_IO			V
V_IL	Low-level input voltage					0.3 V_IO	V
I_IH	High-level input leakage current		V_CC = V_IO = STB = 5.5 V	–2		2	μA
I_IL	Low-level input leakage current		STB = 0 V V_CC= V_IO= 5.5 V,	–20		–2	μA
I_LKG(OFF)	Unpowered leakage current		STB = 5.5V V_CC = V_IO = 0 V	–1	0	1	μA