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ZHCSEG6F December 2015 – May 2025 TCAN330 , TCAN330G , TCAN332 , TCAN332G , TCAN334 , TCAN334G , TCAN337 , TCAN337G

PRODUCTION DATA

封裝選項(xiàng)

機(jī)械數(shù)據(jù) (封裝 | 引腳)

D|8
- MSOI002K
DCN|8
- MPDS099C

散熱焊盤機(jī)械數(shù)據(jù) (封裝 | 引腳)

DCN|8
- PPTD193B

訂購信息

5.5 Electrical Characteristics

over operating free-air temperature range, T_J = –40°C to 150°C. All typical values are at 25°C and supply voltages of V_CC = 3.3 V, R_L = 60 ?, (unless otherwise noted)

PARAMETER			TEST CONDITIONS	MIN	TYP	MAX	UNIT
Supply
I_CC	Supply current Normal Mode	Dominant	See Figure 6-1. TXD = 0V, R_L = 60?, C_L = open, S, STB and SHDN = 0V. Typical Bus Load.			55	mA
		Dominant	See Figure 6-1. TXD = 0V, R_L = 50?, C_L = open, S, STB and SHDN = 0V. High Bus Load.			60
		Dominant with bus fault	See Figure 6-1. TXD = 0V, S, STB and SHDN = 0V, CANH = -12V, R_L = open, C_L = open			180
		Recessive	See Figure 6-1. TXD = V_CC, R_L = 50?, C_L = open, S, STB and SHDN = 0V			3.5
	Supply Current: Silent Mode		See Figure 6-1. TXD = V_CC, R_L = 50?, C_L = open, S = V_CC			2.5
	Supply Current: Standby Mode		T_A < 85°C, STB at V_CC, RXD floating, TXD at V_CC			15	μA
	Supply Current: Standby Mode		STB at V_CC, RXD floating, TXD at V_CC			20
	Supply Current: Shutdown Mode		T_A < 85°C, SHDN at V_CC, RXD floating, TXD at V_CC			1
	Supply Current: Shutdown Mode		SHDN = V_CC, RXD floating, TXD at V_CC			2.5
UV_(VCC)	Rising under voltage detection on V_CC for protected mode				2.2	2.6	V
UV_(VCC)	Falling under voltage detection on V_CC for protected mode			1.65	2	2.5	V
V_HYS(UVVCC)	Hysteresis voltage on UV_(VCC)				200		mV
Driver
V_O(D)	Bus output voltage (dominant)	CANH	See Figure 6-3 and Figure 6-2, TXD = 0V, S, STB and SHDN = 0V, R_L = 60?, C_L = open	2.45		V_CC	V
V_O(D)	Bus output voltage (dominant)	CANL		0.5		1.25	V
V_O(R)	Bus output voltage (recessive)		See Figure 6-3 and Figure 6-2, TXD = V_CC, STB, SHDN = 0V, S = 0V or V_CC ⁽¹⁾, R_L = open (no load)		1.85		V
V_OD(D)	Differential output voltage (dominant)		See Figure 6-3 and Figure 6-2, TXD = 0V, S, STB and SHDN = 0V, 50? ≤ R_L ≤ 65?, C_L = open	1.6		3	V
V_OD(D)	Differential output voltage (dominant)		See Figure 6-3 and Figure 6-2, TXD = 0V, S, STB and SHDN = 0V, 45? ≤ R_L < 50?, C_L = open	1.5		3	V
V_OD(R)	Differential output voltage (recessive)		See Figure 6-3 and Figure 6-2, TXD = V_CC, S, STB and SHDN = 0V, R_L = 60?, C_L = open	–120		12	mV
			T_A < 85°C, See Figure 6-3 and Figure 6-2, TXD = V_CC, S, STB and SHDN = 0V, R_L = open (no load), C_L = open	–50		50
			See Figure 6-3 and Figure 6-2, TXD = V_CC, S, STB and SHDN = 0V, R_L = open (no load), C_L = open	–50		100
V_(SYM)	Output symmetry (dominant and recessive) (CANH_REC + CANL_REC – CANH_DOM – CANL_DOM)		See Figure 6-3 and Figure 6-2, S, STB and SHDN = 0V, R_L = 60?, C_L = open	–400		400	mV
I_OS(DOM)	Short-circuit steady-state output current, Dominant		See Figure 6-9, V_(CANH) = –12V, CANL = open, TXD = 0V	–200			mA
I_OS(DOM)	Short-circuit steady-state output current, Dominant		See Figure 6-9, V_(CANL) = 12V, CANH = open, TXD = 0V			200	mA
I_OS(REC)	Short-circuit steady-state output current, Recessive		See Figure 6-9, –12V ≤ V_BUS ≤ 12V, V_BUS = CANH = CANL, TXD = V_CC	–5		5	mA
Receiver
V_IT	Input threshold voltage, normal modes and selective wake modes		See Figure 6-3 and Table 6-7	500		900	mV
V_HYS	Hysteresis voltage for input threshold, normal modes and selective wake modes				120		mV
V_CM	Common Mode Range: normal and silent modes			–12		12	V
V_IT(STB)	Input Threshold, standby mode		–2V < V_CM < 7V See Figure 6-3 and Table 6-7	400		1150	mV
V_IT(STB)	Input Threshold, standby mode		–12V < V_CM < 12V See Figure 6-3 and Table 6-7	400		1350	mV
I_IOFF(LKG)	Power-off (unpowered) bus input leakage current		T_A < 85°C, CANH = CANL = 3.3V, V_CC to GND via 0Ω and 47kΩ resistor			6	μA
I_IOFF(LKG)	Power-off (unpowered) bus input leakage current		CANH = CANL = 3.3V, V_CC to GND via 0Ω and 47kΩ resistor			12	μA
C_I	Input capacitance to ground (CANH or CANL)					20	pF
C_ID	Differential input capacitance					10	pF
R_ID	Differential input resistance		TXD = V_CC, Normal Mode	30		80	kΩ
R_IN	Input resistance (CANH or CANL)		TXD = V_CC, Normal mode	15		40	kΩ
R_IN(M)	Input resistance matching: [1 – (R_IN(CANH) / R_IN(CANL))] × 100 %		V_(CANH) = V_(CANL)	–3%		3%
TXD Terminal (CAN Transmit Data Input)
V_IH	HIGH level input voltage			2			V
V_IL	LOW level input voltage					0.8	V
I_IH	HIGH level input leakage current		TXD = V_CC = 3.6V	–2.5	0	3	μA
I_IL	LOW level input leakage current		TXD = 0V, V_CC = 3.6V	–4	0	0	μA
I_LKG(OFF)	Unpowered leakage current		TXD = 3.6V, V_CC = 0V	–2	0	2.5	μA
I_(CAP)	Input Capacitance				2.5		pF
RXD Terminal (CAN Receive Data Output)
V_OH	HIGH level output voltage		See Figure 6-3, I_O = –2mA	0.8 x V_CC			V
V_OL	LOW level output voltage		See Figure 6-3, I_O = 2mA		0.2	0.4	V
I_LKG(OFF)	Unpowered leakage current		RXD = 3.6V, V_CC = 0V	–1	0	1	μA
STB/S/SHDN Terminals
V_IH	HIGH level input voltage			2			V
V_IL	LOW level input voltage					0.8	V
I_IH	HIGH level input leakage current		STB, S, SHDN = V_CC = 3.6V	–3	0	10	μA
I_IL	LOW level input leakage current		STB, S, SHDN = 0V, V_CC = 3.6V	–4	0	1	μA
I_LKG(OFF)	Unpowered leakage current		STB, S, SHDN = 3.6V, V_CC = 0V	–3	0	5	μA
FAULT Pin (Fault Output), TCAN337 only
I_CH	Output current high level		FAULT = V_CC, See Figure 6-11	–10			μA
I_CL	Output current low level		FAULT = 0.4V, See Figure 6-11	4	12		mA

(1) The bus output voltage (recessive) is the same if the device is in normal mode with S terminal LOW, or if the device is in silent mode with the S terminal is HIGH.