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ZHCSIY9 October 2018 TS3A5017-Q1

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RGY|16
- MPQF115G

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6.5 Electrical Characteristics for 3.3-VSupply

V₊ = 2.7 V to 3.6 V, T_A = –40°C to125°C (unless otherwise noted)⁽¹⁾

PARAMETER		TEST CONDITIONS			MIN	TYP	MAX	UNIT
Analog Switch
V_D, V_S	Analog signal range				0		V₊	V
r_on	ON-state resistance	0 ≤ V_S ≤ V₊, I_D = –32 mA,	Switch ON, see Figure 12	T_A = 25°C V₊ = 3 V		11		Ω
r_on	ON-state resistance	0 ≤ V_S ≤ V₊, I_D = –32 mA,	Switch ON, see Figure 12	T_A = Full V₊ = 3 V			16	Ω
Δr_on	ON-state resistance match between channels	V_S = 2.1 V, I_D = –32 mA,	Switch ON, see Figure 12	T_A = 25°C V₊ = 3 V		1		Ω
Δr_on	ON-state resistance match between channels	V_S = 2.1 V, I_D = –32 mA,	Switch ON, see Figure 12	T_A = Full V₊ = 3 V			5	Ω
r_on(flat)	ON-state resistance flatness	0 ≤ V_S ≤ V₊, I_D = –32 mA,	Switch ON, see Figure 12	T_A = 25°C V₊ = 3 V		7		Ω
r_on(flat)	ON-state resistance flatness	0 ≤ V_S ≤ V₊, I_D = –32 mA,	Switch ON, see Figure 12	T_A = Full V₊ = 3 V			12	Ω
I_S(OFF)	S OFF leakage current	V_S = 1 V, V_D = 3 V, or V_S = 3 V, V_D = 1 V,	Switch OFF, see Figure 13	T_A = 25°C V₊ = 3.6 V		0.05		μA
I_S(OFF)		V_S = 1 V, V_D = 3 V, or V_S = 3 V, V_D = 1 V,		T_A = Full V₊ = 3.6 V	–0.3		0.3
I_SPWR(OFF)		V_S = 0 to 3.6 V, V_D = 3.6 V to 0,		T_A = 25°C V₊ = 0 V		0.5
I_SPWR(OFF)		V_S = 0 to 3.6 V, V_D = 3.6 V to 0,		T_A = Full V₊ = 0 V	–10		10
I_D(OFF)	D OFF leakage current	V_S = 1 V, V_D = 3 V, or V_S = 3 V, V_D = 1 V,	Switch OFF, see Figure 13	T_A = 25°C V₊ = 3.6 V		0.05		μA
I_D(OFF)		V_S = 1 V, V_D = 3 V, or V_S = 3 V, V_D = 1 V,		T_A = Full V₊ = 3.6 V	–0.3		0.3
I_DPWR(OFF)		V_D = 0 to 3.6 V, V_S = 3.6 V to 0,		T_A = 25°C V₊ = 0 V		0.5
I_DPWR(OFF)		V_D = 0 to 3.6 V, V_S = 3.6 V to 0,		T_A = Full V₊ = 0 V	–20		20
I_S(ON)	S ON leakage current	V_S = 1 V, V_D = Open, or V_S = 3 V, V_D = Open,	Switch ON, see Figure 14	T_A = 25°C V₊ = 3.6 V		0.05		μA
I_S(ON)	S ON leakage current	V_S = 1 V, V_D = Open, or V_S = 3 V, V_D = Open,	Switch ON, see Figure 14	T_A = Full V₊ = 3.6 V	–0.3		0.3	μA
I_D(ON)	D ON leakage current	V_D = 1 V, V_S = Open, or V_D = 3 V, V_S = Open,	Switch ON, see Figure 14	T_A = 25°C V₊ = 3.6 V		0.05		μA
I_D(ON)	D ON leakage current	V_D = 1 V, V_S = Open, or V_D = 3 V, V_S = Open,	Switch ON, see Figure 14	T_A = Full V₊ = 3.6 V	–0.3		0.3	μA
Digital Control Inputs (IN1, IN2, EN)⁽²⁾
V_IH	Input logic high			T_A = Full	2		V₊	V
V_IL	Input logic low			T_A = Full	0		0.8	V
I_IH, I_IL	Input leakage current	V_I = V₊ or 0		T_A = 25°C V₊ = 3.6 V		0.05		μA
I_IH, I_IL	Input leakage current	V_I = V₊ or 0		T_A = Full V₊ = 3.6 V	–1		1	μA
Q_C	Charge injection	V_GEN = 0, R_GEN = 0, C_L = 0.1 nF,	See Figure 21	T_A = 25°C V₊ = 3.3 V		5		pC
C_S(OFF)	S OFF capacitance	V_S = V₊ or GND, Switch OFF,	See Figure 15	T_A = 25°C V₊ = 3.3 V		4.5		pF
C_D(OFF)	D OFF capacitance	V_D = V₊ or GND, Switch OFF,	See Figure 15	T_A = 25°C V₊ = 3.3 V		19		pF
C_S(ON)	S ON capacitance	V_S = V₊ or GND, Switch ON,	See Figure 15	T_A = 25°C V₊ = 3.3 V		27		pF
C_D(ON)	D ON capacitance	V_D = V₊ or GND, Switch ON,	See Figure 15	T_A = 25°C V₊ = 3.3 V		27		pF
C_I	Digital input capacitance	V_I = V₊ or GND,	See Figure 15	T_A = 25°C V₊ = 3.3 V		3		pF
BW	Bandwidth	R_L = 50 Ω, Switch ON,	See Figure 17	T_A = 25°C V₊ = 3.3 V		165		MHz
O_ISO	OFF isolation	R_L = 50 Ω, f = 1 MHz,	See Figure 18	T_A = 25°C V₊ = 3.3 V		–69		dB
O_ISO	OFF isolation	R_L = 50 Ω, f = 10 MHz,	See Figure 18	T_A = 25°C V₊ = 3.3 V		–49		dB
X_TALK	Crosstalk	R_L = 50 Ω, f = 1 MHz,	See Figure 19	T_A = 25°C V₊ = 3.3 V		–69		dB
X_TALK(ADJ)	Crosstalk adjacent	R_L = 50 Ω, f = 1 MHz,	See Figure 20	T_A = 25°C V₊ = 3.3 V		–80		dB
THD	Total harmonic distortion	R_L = 600 Ω, C_L = 50 pF,	f = 20 Hz to 20 kHz, see Figure 22	T_A = 25°C V₊ = 3.3 V		0.25		%
Supply
I₊	Positive supply current	V_I = V₊ or GND,	Switch ON or OFF	T_A = 25°C V₊ = 3.6 V		2.5	7	μA
I₊	Positive supply current	V_I = V₊ or GND,	Switch ON or OFF	T_A = Full V₊ = 3.6 V			10	μA

(1) The algebraic convention, whereby the most negative value is aminimum and the most positive value is a maximum

(2) All unused digital inputs of the device must be held atV₊or GND to ensure proper device operation. Refer to the TI applicationreport, Implications of Slow or Floating CMOS Inputs, literaturenumber SCBA004.