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ZHCSMC0A December 2020 – April 2022 TLIN1029A-Q1

PRODUCTION DATA

封裝選項

機械數據 (封裝 | 引腳)

D|8
- MSOI002K
DRB|8
- MPDS118K

散熱焊盤機械數據 (封裝 | 引腳)

DRB|8
- QFND619

訂購信息

7.6 Electrical Characteristics

parameters valid across -40℃ ≤ T_A ≤ 125℃ (unless otherwise noted)

PARAMETER		TEST CONDITIONS	MIN	TYP	MAX	UNIT
Power Supply
V_SUP	Operational supply voltage (ISO/DIS 17987 Param 10)	Device is operational beyond the LIN defined nominal supply voltage range See Figure 8-1 and Figure 8-2	4		36	V
V_SUP	Nominal supply voltage (ISO/DIS 17987 Param 10)	Normal and Standby Modes: ramp V_SUP while LIN signal is a 10 kHz square wave with 50 % duty cycle and 36V swing. See Figure 8-1 and Figure 8-2	4		36	V
V_SUP	Nominal supply voltage (ISO/DIS 17987 Param 10)	Sleep Mode	4		36	V
UV_SUP	Under voltage V_SUP threshold	Min is falling edge and Max is rising edge	2.9		3.85	V
UV_HYS	Delta hysteresis voltage for V_SUP under voltage threshold			0.2		V
I_SUP	Supply current	Normal Mode: EN = high, bus dominant: total bus load where R_LIN > 500 Ω and C_LIN < 10 nF		1	5	mA
I_SUP	Supply current	Standby Mode: EN = low, bus dominant: total bus load where R_LIN > 500 Ω and C_LIN < 10 nF		1	2.1	mA
I_SUP	Supply current	Normal Mode: EN = high, bus recessive (LIN = V_SUP)		300	650	μA
		Standby Mode: EN = low, bus recessive (LIN = V_SUP)		10	30	μA
		Sleep Mode: 4.0 V < V_SUP ≤ 14 V, LIN = VSUP, EN = 0 V, TXD and RXD floating		8	12	μA
		Sleep Mode: 14 V < V_SUP ≤ 36 V, LIN = V_SUP, EN = 0 V, TXD and RXD floating			20	μA
TSD	Thermal shutdown		165			℃
TSD_(HYS)	Thermal shutdown hysteresis			15		℃
RXD Output Pin (Open Drain)
V_OL	Output low voltage	Based upon external pull-up to V_CC⁽⁴⁾			0.6	V
I_OL	Low level output current, open drain	LIN = 0 V, RXD = 0.4 V	1.5			mA
I_ILG	Leakage current, high-level	LIN = V_SUP, RXD = 5 V	–5	0	5	μA
TXD Input Pin
V_IL	Low level input voltage		–0.3		0.8	V
V_IH	High level input voltage		2		5.25	V
I_ILG	Low level input leakage current	TXD = low	–5	0	5	μA
R_TXD	Internal pull-down resistor value		125	350	800	kΩ
LIN PIN
V_OH	LIN recessive high-level output voltage ⁽³⁾	TXD = high, I_O = 0 mA, 7 V ≤ V_SUP ≤ 36 V	0.85			V_SUP
V_OH	LIN recessive high-level output voltage ⁽¹⁾ ⁽²⁾	TXD = high, I_O = 0 mA, 7 V ≤ V_SUP ≤ 18 V	0.8			V_SUP
V_OH	LIN recessive high-level output voltage ⁽³⁾	TXD = high, I_O = 0 mA, 4 V ≤ V_SUP < 7 V	3			V
V_OL	LIN dominant low-level output voltage ⁽³⁾	TXD = low, 7 V ≤ V_SUP ≤ 36 V			0.2	V_SUP
V_OL	LIN dominant low-level output voltage ⁽¹⁾ ⁽²⁾	TXD = low, 7 V ≤ V_SUP ≤ 18 V			0.2	V_SUP
V_OL	LIN dominant low-level output voltage ⁽³⁾	TXD = low, 4 V ≤ V_SUP < 7 V			1.2	V
V_{SUP_NON_OP}	VSUP where impact of recessive LIN bus < 5% (ISO/DIS 17987 Param 11)	TXD & RXD open LIN = 4 V to 45 V	–0.3		45	V
I_{BUS_LIM}	Limiting current (ISO/DIS 17987 Param 12)	TXD = 0 V, V_LIN = 18 V, V_SUP = 18 V	40	90	200	mA
I_{BUS_PAS_dom}	Receiver leakage current, dominant (ISO/DIS 17987 Param 13)	LIN = 0 V, V_SUP = 12 V Driver off/recessive Figure 8-6	–1			mA
I_{BUS_PAS_rec1}	Receiver leakage current, recessive (ISO/DIS 17987 Param 14)	LIN > V_SUP, 4 V ≤ V_SUP ≤ 36 V Driver off; Figure 8-7			20	μA
I_{BUS_PAS_rec2}	Receiver leakage current, recessive (ISO/DIS 17987 Param 14)	LIN = V_SUP, Driver off; Figure 8-7	–5		5	μA
I_{BUS_NO_GND}	Leakage current, loss of ground (ISO/DIS 17987 Param 15)	GND = V_SUP, V_SUP = 18 V, R_Meas = 1 kΩ, 0 V < V_LIN < 18 V; Figure 8-8	–1		1	mA
I_{leak gnd(dom)}	Leakage current, loss of ground ⁽⁵⁾	V_SUP = 8 V, GND = open, V_SUP = 18 V, GND = open R_Commander = 1 kΩ, C_L = 1 nF R_Responder = 20 kΩ, C_L = 1 nF LIN = dominant	-1		1	mA
I_{leak gnd(rec)}	Leakage current, loss of ground ⁽⁵⁾	V_SUP = 8 V, GND = open, V_SUP = 18 V, GND = open R_Commander = 1 kΩ, C_L = 1 nF R_Responder = 20 kΩ, C_L = 1 nF LIN = recessive	-100		100	μA
I_{BUS_NO_BAT}	Leakage current, loss of supply (ISO/DIS 17987 Param 16)	LIN = 18 V, V_SUP = GND; Figure 8-9			5	μA
V_BUSdom	Low level input voltage (ISO/DIS 17987 Param 17) ⁽³⁾	LIN dominant (including LIN dominant for wake up) See Figure 8-4, Figure 8-3			0.4	V_SUP
V_BUSrec	High level input voltage (ISO/DIS 17987 Param 18) ⁽³⁾	LIN recessive See Figure 8-4, Figure 8-3	0.6			V_SUP
V_IH	LIN recessive high-level input voltage ⁽¹⁾ ⁽²⁾	7 V ≤ V_SUP ≤ 18 V	0.47		0.6	V_SUP
V_IL	LIN dominant low-level input voltge ⁽¹⁾ ⁽²⁾	7 V ≤ V_SUP ≤ 18 V	0.4		0.53	V_SUP
V_{BUS_CNT}	Receiver center threshold (ISO/DIS 17987 Param 19)	V_{BUS_CNT} = (V_BUSrec + V_BUSdom)/2 See Figure 8-4, Figure 8-3	0.475	0.5	0.525	V_SUP
V_HYS	Hysteresis voltage (ISO/DIS 17987 Param 20)	V_HYS = (V_BUSrec - V_BUSdom) See Figure 8-4, Figure 8-3			0.175	V_SUP
V_HYS	Hysteresis voltage (SAE J2602)	V_HYS = V_IH - V_ILSee Figure 8-4, Figure 8-3	0.07		0.175	V_SUP
V_{SERIAL_DIODE}	Serial diode LIN termination pull-up path	I_{SERIAL_DIODE} = 10 μA	0.4	0.7	1	V
R_PU	Internal pull-up resistor to V_SUP	Normal and standby modes	20	45	60	kΩ
I_RSLEEP	Pull-up current source to V_SUP	Sleep mode, V_SUP = 14 V, LIN = GND	–20		–2	μA
C_LINPIN	Capacitance of the LIN pin	V_SUP = 14 V			25	pF
EN Input Pin
V_IL	Low level input voltage		–0.3		0.8	V
V_IH	High level input voltage		2		5.25	V
V_IT	Hysteresis voltage	By design and characterization		50	500	mV
I_ILG	Low level input current	EN = low	–5	0	5	μA
R_EN	Internal pull-down resistor		125	350	800	kΩ

(1) SAE 2602 commander node load conditions: 5.5 nF/4 kΩ and 899 pF/20 kΩ

(2) SAE 2602 responder node load conditions: 5.5 nF/875 Ω and 899 pF/900 Ω

(3) ISO 17987 bus load conditions (C_LINBUS, R_LINBUS) include 1 nF/1 kΩ; 6.8 nF/660 Ω; 10 nF/500 Ω.

(4) RXD uses open drain output structure therefore V_OL level is based upon microcontroller supply voltage V_CC.

(5) I_{leak gnd} = (V_BAT - V_LIN)/R_Load