SBOSAC9 Data sheet

SBOSAC9E August 2022 – July 2024 OPA2992-Q1 , OPA4992-Q1 , OPA992-Q1

PRODUCTION DATA

Package Options

Mechanical Data (Package|Pins)

DCK|5
- MPDS025I
DBV|5
- MPDS018S

Thermal pad, mechanical data (Package|Pins)

Orderable Information

5.7 Electrical Characteristics

For V_S = (V+) – (V–) = 2.7V to 40V (±1.35V to ±20V) at T_A = 25°C, R_L = 10kΩ connected to V_S / 2, V_CM = V_S / 2, and V_OUT = V_S / 2, unless otherwise noted.

PARAMETER		TEST CONDITIONS		MIN	TYP	MAX	UNIT
OFFSET VOLTAGE
V_OS	Input offset voltage	V_CM = V–			±0.21	±1.03	mV
V_OS	Input offset voltage	V_CM = V–	T_A = –40°C to 125°C			±1.2	mV
dV_OS/dT	Input offset voltage drift	V_CM = V–	T_A = –40°C to 125°C		±0.25		µV/℃
PSRR	Input offset voltage versus power supply	OPA992-Q1, OPA2992-Q1, V_CM = V–, V_S = 5V to 40V	T_A = –40°C to 125°C		±0.2	±1.3	μV/V
		OPA4992-Q1, V_CM = V–, V_S = 5V to 40V			±0.4	±1.8
		OPA992-Q1, OPA2992-Q1, OPA4992-Q1, V_CM = V–, V_S = 2.7V to 40V⁽¹⁾			±0.8	±7
	DC channel separation				0.4		µV/V
INPUT BIAS CURRENT
I_B	Input bias current				±10		pA
I_OS	Input offset current				±10		pA
NOISE
E_N	Input voltage noise	f = 0.1Hz to 10Hz			2.77		μV_PP
E_N	Input voltage noise	f = 0.1Hz to 10Hz			0.49		µV_RMS
e_N	Input voltage noise density	f = 1kHz			7		nV/√Hz
e_N	Input voltage noise density	f = 10kHz			4.4		nV/√Hz
i_N	Input current noise density	f = 1kHz			60		fA/√Hz
INPUT VOLTAGE RANGE
V_CM	Common-mode voltage range			(V–)		(V+)	V
CMRR	Common-mode rejection ratio	V_S = 40V, V– < V_CM < (V+) – 2V (PMOS pair)	T_A = –40°C to 125°C	100	115		dB
		V_S = 5V, V– < V_CM < (V+) – 2V (PMOS pair)⁽¹⁾		75	98
		V_S = 2.7V, V– < V_CM < (V+) – 2V (PMOS pair)			90
		V_S = 2.7 – 40V, (V+) – 1V < V_CM < V+ (NMOS pair)			79
		(V+) – 2V < V_CM < (V+) – 1V		See Offset Voltage vs CommonMode Voltage (Transition Region)
INPUT IMPEDANCE
Z_ID	Differential				100 \|\| 9		MΩ \|\| pF
Z_ICM	Common-mode				6 \|\| 1		TΩ \|\| pF
OPEN-LOOP GAIN
A_OL	Open-loop voltage gain	V_S = 40V, V_CM = V_S / 2, (V–) + 0.1V < V_O < (V+) – 0.1V		120	142		dB
		V_S = 40V, V_CM = V_S / 2, (V–) + 0.12V < V_O < (V+) – 0.12V	T_A = –40°C to 125°C		142
		V_S = 5V, V_CM = V_S / 2, (V–) + 0.1V < V_O < (V+) – 0.1V⁽¹⁾		104	125
			T_A = –40°C to 125°C		125
		V_S = 2.7V, V_CM = V_S / 2, (V–) + 0.1V < V_O < (V+) – 0.1V⁽¹⁾		90	105
			T_A = –40°C to 125°C		105
FREQUENCY RESPONSE
GBW	Gain-bandwidth product				10.6		MHz
SR	Slew rate	V_S = 40V, G = +1, V_STEP = 10V, C_L = 20pF⁽³⁾			32		V/μs
t_S	Settling time	To 0.1%, V_S = 40V, V_STEP = 10V, G = +1, C_L = 20pF			0.65		μs
		To 0.1%, V_S = 40V, V_STEP = 2V, G = +1, C_L = 20pF			0.3
		To 0.01%, V_S = 40V, V_STEP = 10V, G = +1, C_L = 20pF			0.86
		To 0.01%, V_S = 40V, V_STEP = 2V, G = +1, C_L = 20pF			0.44
	Phase margin	G = +1, R_L = 10kΩ, C_L = 20pF			64		°
	Overload recovery time	V_IN × gain > V_S			170		ns
THD+N	Total harmonic distortion + noise	V_S = 40V, V_O = 3V_RMS, G = 1, f = 1kHz, R_L = 10kΩ			0.00005%
		V_S = 40V, V_O = 3V_RMS, G = 1, f = 1kHz, R_L = 10kΩ			126		dB
		V_S = 10V, V_O = 3V_RMS, G = 1, f = 1kHz, R_L = 128Ω			0.0032%
		V_S = 10V, V_O = 3V_RMS, G = 1, f = 1kHz, R_L = 128Ω			90		dB
		V_S = 10V, V_O = 0.4V_RMS, G = 1, f = 1kHz, R_L = 32Ω			0.00032%
		V_S = 10V, V_O = 0.4V_RMS, G = 1, f = 1kHz, R_L = 32Ω			110		dB
OUTPUT
	Voltage output swing from rail	Positive and negative rail headroom	V_S = 40V, R_L = no load		7		mV
			V_S = 40V, R_L = 10kΩ		48	60
			V_S = 40V, R_L = 2kΩ		220	300
			V_S = 2.7V, R_L = no load		0.5
			V_S = 2.7V, R_L = 10kΩ		5	20
			V_S = 2.7V, R_L = 2kΩ		20	50
I_SC	Short-circuit current				±65⁽²⁾		mA
C_LOAD	Capacitive load drive			See Phase Margin vs Capacitive Load			pF
Z_O	Open-loop output impedance	I_O = 0A		See Open-Loop Output Impedance vs Frequency			Ω
POWER SUPPLY
I_Q	Quiescent current per amplifier	OPA2992-Q1, OPA4992-Q1, I_O = 0A			2.4	2.8	mA
		OPA2992-Q1, OPA4992-Q1, I_O = 0A	T_A = –40°C to 125°C			2.84
		OPA992, I_O = 0A			2.48	2.92
		OPA992, I_O = 0A	T_A = –40°C to 125°C			2.98

(1) Specified by characterization only.

(2) At high supply voltage, placing the OPAx992 in a sudden short to mid-supply or ground will lead to rapid thermal shutdown. Output current greater than I_SC can be achieved if rapid thermal shutdown is avoided as per Output Voltage Swing vs Output Current.

(3) See Slew Rate vs Input Step Voltage for more information.