JAJSQY1 データシート

JAJSQY1B August 2023 – April 2024 THVD4431

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）

RHA|40
- MPQF135D

サーマルパッド・メカニカル・データ

RHA|40
- QFND740

発注情報

5.7 Electrical Characteristics

over operating free-air temperature range (unless otherwise noted). All typical values are at 25°C and supply voltage of V_CC = 5 V, V_IO = 3.3 V , unless otherwise noted.

PARAMETER		TEST CONDITIONS			MIN	TYP	MAX	UNIT
Driver_RS-485
\|V_OD\|	Driver differential output voltage magnitude	R_L= 60 Ω, –7 V ≤ V_test ≤ 12 V (See Figure 6-1 )			1.5	2		V
		R_L= 60 Ω, –7 V ≤ V_test ≤ 12 V, 4.5 V ≤ V_CC ≤ 5.5 V (See Figure 6-1 )			2.1	3		V
		R_L= 100 Ω (See Figure 6-2 )			2	2.5		V
		R_L = 54 Ω, 4.5 V ≤ V_CC ≤ 5.5 V (See Figure 6-2 )			2.1	3.3		V
		R_L = 54 Ω (See Figure 6-2 )			1.5	3.3		V
Δ\|V_OD\|	Change in magnitude of differential output voltage	R_L = 54 Ω or 100 Ω (See Figure 6-2 )			–50		50	mV
V_OC	Common-mode output voltage	R_L = 54 Ω or 100 Ω (See Figure 6-2 )				V_CC/2	3	V
ΔV_OC(SS)	Change in steady-state common-mode output voltage	R_L = 54 Ω or 100 Ω (See Figure 6-2 )			–50		50	mV
I_OS	Short-circuit output current (bus terminals)	DIR = V_IO, -7 V ≤ (V_R2 or V_R1) ≤ 12 V, or R1 shorted to R2			–250		250	mA
I_OZD	Driver High impedance output leakage current on R1 and R2 in Full duplex mode	MODE2, MODE1, MODE0 = 011 , TERM_TX = GND, DIR = GND, V_CC = GND or 5.5V, V_O = -7V, +12V			-125		125	µA
I_OZD		MODE2, MODE1, MODE0 = 011, TERM_TX = V_IO, DIR = GND, V_CC = 5.5V, V_O = -7V, +12V			- 325		350	µA
Receiver_RS-485
I_I	Bus input current (termination disabled)	Half and full duplex modes, DIR = 0 V, V_CC and V_IO = 0 V or 5.5 V		V_I = 12 V		75	125	μA
I_I	Bus input current (termination disabled)			V_I = –7 V	–125	–70		μA
I_RXT	Receiver bus input leakage current with termination enabled	Full duplex mode, V_CC and V_IO = 5.5 V, TERM_RX = V_IO		VI = - 7 to 12 V	-325		325	μA
V_TH+	Positive-going input threshold voltage⁽¹⁾	Over common-mode range of - 7 V to 12 V				- 70	- 40	mV
V_TH-	Negative-going input threshold voltage⁽¹⁾				–200	–150		mV
V_HYS	Input hysteresis				25	80		mV
C_A,B	Input differential capacitance	Measured between R3 and R4, f = 1 MHz				45		pF
V_OH	Output high voltage, L2 pin	I_OH = –4 mA, V_IO = 3 to 3.6 V or 4.5 V to 5.5 V			V_IO – 0.4	V_IO – 0.2		V
V_OL	Output low voltage, L2 pin	I_OL = 4 mA, V_IO = 3 to 3.6 V or 4.5 V to 5.5 V				0.2	0.4	V
V_OH	Output high voltage, L2 pin	I_OH = –2 mA, V_IO = 1.65 to 1.95 V or 2.25 V to 2.75 V			V_IO – 0.4	V_IO – 0.2		V
V_OL	Output low voltage, L2 pin	I_OL = 2 mA, V_IO = 1.65 to 1.95 V or 2.25 V to 2.75 V				0.2	0.4	V
I_OZ	Output high-impedance current, L2 pin	V_O = 0 V or V_IO, DIR = VIO, MODE2, MODE1, MODE0= 010 (half duplex mode)			–2		2	µA
Driver_RS-232
V_OH	High-level output voltage	All DOUT (R3, R4, R6) at R_L = 3 kΩ to GND, DIN (L3, L4, L6) = GND; V_CC = 3 V to 3.6 V			5	5.5	7.2	V
V_OL	Low-level output voltage	All DOUT (R3, R4, R6) at R_L = 3 kΩ to GND, DIN (L3, L4, L6) = V_IO; V_CC = 3 V to 3.6 V			–7.2	–5.5	-5	V
V_OH	High-level output voltage	All DOUT (R3, R4, R6) at R_L = 3 kΩ to GND, DIN (L3, L4, L6) = GND; V_CC = 4.5 V to 5.5 V			7.8	9	11	V
V_OL	Low-level output voltage	All DOUT (R3, R4, R6) at R_L = 3 kΩ to GND, DIN (L3, L4, L6) = V_IO; V_CC = 4.5 V to 5.5 V			–11	–9	-7.8	V
I_OS	Short-circuit output current ⁽²⁾	V_CC = 3.6 V	V_O = 0 V			±35	±60	mA
I_OS	Short-circuit output current ⁽²⁾	V_CC = 5.5 V	V_O = 0 V			±35	±60	mA
r_o	Output resistance on R3, R4, R6	V_CC = 0 V, V₊ = 0 V, and V_– = 0 V	V_O = ±2 V		300	10M		Ω
I_off	Output leakage current on R3, R4, R6	SHDN = GND	V_O = ±12 V	V_CC = 3 to 3.6 V			±125	μA
I_off	Output leakage current on R3, R4, R6	SHDN = GND	V_O = ±10 V	V_CC = 4.5 to 5.5 V			±125	μA
Receiver_RS-232
V_OH	High-level output voltage L1/L2/L5/L7/L8	I_OH = –4 mA, V_IO = 3 to 3.6 V or 4.5 V to 5.5 V			V_IO – 0.5	V_IO – 0.2		V
V_OH	High-level output voltage L1/L2/L5/L7/L8	I_OH = –2 mA, V_IO = 1.65 to 1.95 V or 2.25 V to 2.75 V			V_IO – 0.48	V_IO – 0.2		V
V_OL	Low-level output voltage L1/L2/L5/L7/L8	I_OL = 4 mA, V_IO = 3 to 3.6 V or 4.5 V to 5.5 V					0.4	V
V_OL	Low-level output voltage L1/L2/L5/L7/L8	I_OL = 2 mA, V_IO = 1.65 to 1.95 V or 2.25 V to 2.75 V					0.4	V
V_IT+	Positive-going input threshold voltage on RS-232 receiver inputs (R1, R2, R5, R7, R8)	V_CC = 3.3 V				1.6	2.4	V
V_IT+		V_CC = 5 V				1.9	2.4	V
V_IT–	Negative-going input threshold voltage on RS-232 receiver inputs (R1, R2, R5, R7, R8)	V_CC = 3.3 V			0.6	1.1		V
V_IT–		V_CC = 5 V			0.8	1.4		V
V_hys	Input hysteresis on receiver inputs (V_IT+ – V_IT–)				0.4	0.5		V
I_off	Output leakage current on receiver output pins L1/L2/L5/L7/L8	SHDN = 0 V				±0.05	±10	μA
r_I	Input resistance on receiver input pins	-15 V ≤ V_I ≤ 15 V			3	5	7	kΩ
Thermal Protection
T_SHDN	Thermal shutdown threshold	Temperature rising			150	170		°C
T_HYS	Thermal shutdown hysteresis					15		°C
Supply
UV_{VCC (rising)}	Rising under-voltage threshold on V_CC					2.5	2.8	V
UV_{VCC (falling)}	Falling under-voltage threshold on V_CC				1.9	2.1		V
UV_VCC(hys)	Hysteresis on under-voltage of V_CC				100	400		mV
UV_{VIO (rising)}	Rising under-voltage threshold on V_IO					1.5	1.6	V
UV_{VIO (falling)}	Falling under-voltage threshold on V_IO				1.2	1.4		V
UV_VIO(hys)	Hysteresis on under-voltage of V_IO				85	100		mV
I_{CC_SHDN}	Supply current in shutdown mode	V_CC = 4.5 V to 5.5 V, SHDN = GND, All other logic input pins floating, no load on bus, T_A ≤ 125 ℃				5	20	µA
		V_CC = 3 V to 3.6 V, SHDN = GND, All other logic input pins floating, no load on bus, T_A ≤ 125 ℃				3	15	µA
		V_CC = 4.5 V to 5.5 V, SHDN = GND, All other logic input pins floating, no load on bus, T_A ≤ 105 ℃				5	15	µA
		V_CC = 3 V to 3.6 V, SHDN = GND, All other logic input pins floating, no load on bus, T_A ≤ 105 ℃				3	10	µA
I_{IO_SHDN}	Logic supply current in shutdown mode	V_IO = 1.65 V to 5.5 V, SHDN = GND, All other logic input pins floating					2	µA
I_{CC_485}	Supply current (quiescent), V_CC = 4.5 V to 5.5 V TERM_RX, TERM_TX= Floating or low, SLR = X	Driver and receiver enabled, DIR = V_IO, MODE2, MODE1, MODE0 = 011 (Full duplex)		No load		1.7	3.4	mA
		Driver enabled, receiver disabled, DIR = V_IO, MODE2, MODE1, MODE0 = 010 (Half duplex)		No load		1.3	2.8	mA
		Driver disabled, receiver enabled, DIR = GND, MODE2, MODE1, MODE0 = 010 (Half duplex)		No load		0.8	1.5	mA
I_{CC_485}	Supply current (quiescent), V_CC = 3 V to 3.6 V TERM_RX, TERM_TX= Floating or low, SLR = X	Driver and receiver enabled, DIR = V_IO, MODE2, MODE1, MODE0 = 011 (Full duplex)		No load		1.5	2.8	mA
		Driver enabled, receiver disabled, DIR = V_IO, MODE2, MODE1, MODE0 = 010 (Half duplex)		No load		1	2.3	mA
		Driver disabled, receiver enabled, DIR = GND, MODE2, MODE1, MODE0 = 010 (Half duplex)		No load		0.7	1.3	mA
I_{IO_485}	Logic supply current (quiescent), V_IO = 3 to 3.6 V TERM_RX, TERM_TX= Floating	Driver disabled, Receiver enabled, SLR = GND, DIR = GND; MODE2, MODE1, MODE0 = 010 (half duplex)		No load		7	17	µA
I_{IO_485}		Driver disabled, Receiver enabled, SLR = V_IO; DIR = GND; MODE2, MODE1, MODE0 = 010 (half duplex)		No load		8	21	µA
I_{CCDT_485}	Supply current in RS-485 driver termination mode	Driver enabled with termination ON; MODE2, MODE1, MODE0 = 011 (full duplex)		DIR= V_IO, TERM_TX = V_IO		38	50	mA
I_{CCRT_485}	Supply current in RS-485 receiver termination mode	Receiver enabled with termination ON; MODE2, MODE1, MODE0 = 011 (full duplex)		DIR = GND, TERM_RX = V_IO		1	1.5	mA
I_{CC_RS232}	Supply current in RS-232 mode	MODE2, MODE1, MODE0 = 001, SHDN = V_IO; other logic inputs floating		No load		4	6	mA
I_{CC_RS232_LB}	Supply current in RS-232 loopback mode	MODE2 = x, MODE1 = 0, MODE0 = 0; L3 = L4 = L6 = static logic high, -40 ℃ ≤ T_A ≤ 85 ℃		No extra load on RS-232 drivers or on logic output		25	31	mA
I_{CC_RS485_LB}	Supply current in RS-485 loopback mode	MODE2 = MODE1= MODE0 = V_IO; L3 = static logic high		No load on bus or logic output		3	4	mA
On-Chip termination resistor_RS-485
R_{TERM_TX}	120 Ω termination across Driver output R1/R2 terminals	MODE2, MODE1, MODE0 = 011 (Full duplex) or 010 (half duplex); DIR = GND, TERM_TX = V_IO, V_R2R1 = 2 V, V_R1 = -7 V, 0 V, 10 V; See Figure 6-9			102	120	138	Ω
R_{TERM_RX}	120 Ω termination across receiver output R3/R4 terminals	MODE2, MODE1, MODE0 = 011 (Full duplex); TERM_RX = V_IO, V_R3R4 = 2 V, V_R4 = -7 V, 0 V, 10 V; See Figure 6-9			102	120	138	Ω
Logic
I_IN	Input current (L3, L4, L6, DIR, SHDN, SLR, TERM_TX, TERM_RX, MODE2, MODE1, MODE0)	1.65 V ≤ V_IO ≤ 5.5 V, 0 V ≤ V_IN ≤ V_IO			-20		5	µA
V_IT+(IN)	Rising threshold: logic inputs	1.65 V ≤ V_IO ≤ 5.5 V				0.6*V_IO	0.7*V_IO	V
V_IT-(IN)	Falling threshold: logic inputs				0.3*V_IO	0.4*V_IO		V
V_IN(HYS)	Input threshold: logic inputs				0.1*V_IO	0.2*V_IO		V

(1) Under any specific conditions, V_TH+ is assured to be at least V_HYS higher than V_TH–.

(2)
Short-circuit durations should be controlled to prevent exceeding the device absolute power dissipation ratings, and not more than one
output should be shorted at a time.