av每日更新手机观看,无码日本亚洲一区久久精品

SBOS424C March 2008 – November 2015 PGA112 , PGA113 , PGA116 , PGA117

PRODUCTION DATA.

封裝選項(xiàng)

請(qǐng)參考 PDF 數(shù)據(jù)表獲取器件具體的封裝圖。

機(jī)械數(shù)據(jù) (封裝 | 引腳)

DGS|10

散熱焊盤機(jī)械數(shù)據(jù) (封裝 | 引腳)

訂購(gòu)信息

7 Specifications

7.1 Absolute Maximum Ratings

Over operating free-air temperature range, unless otherwise noted.⁽¹⁾

	MIN	MAX	UNIT
Supply voltage		7	V
Signal input terminals, voltage⁽²⁾	GND – 0.5	AV_DD + 0.5	V
Signal input terminals, current⁽²⁾		±10	mA
Output short circuit	Continuous
Operating temperature	–40	125	°C
Junction temperature		150	°C
Storage temperature	–65	150	°C

(1) Stresses above these ratings may cause permanent damage. Exposure to absolute maximum conditions for extended periods may degrade device reliability. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those specified is not implied.

(2) Input terminals are diode-clamped to the power-supply rails. Input signals that can swing more than 0.5 V beyond the supply rails should be current-limited to 10 mA or less.

7.2 ESD Ratings

			VALUE	UNIT
V_(ESD)	Electrostatic discharge	Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001⁽¹⁾	±3000	V
		Charged-device model (CDM), per JEDEC specification JESD22-C101⁽²⁾	±1000
		Machine Model (MM)	±300

(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.

(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.

7.3 Recommended Operating Conditions

over operating free-air temperature range (unless otherwise noted)

	MIN	NOM	MAX	UNIT
AV_DD	2.2	5	5.5	V
DV_DD	2.2	5	5.5	V
Operating temperature	–40	25	125	°C

7.4 Thermal Information

THERMAL METRIC⁽¹⁾		PGA112, PGA113	PGA116, PGA117	UNIT
		DGS (VSSOP)	PW (TSSOP)
		10 PINS	20 PINS
R_θJA	Junction-to-ambient thermal resistance	98.3	100.3	°C/W
R_θJC(top)	Junction-to-case (top) thermal resistance	57	36.9	°C/W
R_θJB	Junction-to-board thermal resistance	51.2	50.6	°C/W
ψ_JT	Junction-to-top characterization parameter	1.3	2.6	°C/W
ψ_JB	Junction-to-board characterization parameter	36.9	50.2	°C/W
R_θJC(bot)	Junction-to-case (bottom) thermal resistance	4.8	N/A	°C/W

(1) For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.

7.5 Electrical Characteristics: V_S = AV_DD = DV_DD = 5 V

at T_A = 25°C, R_L = 10kΩ//C_L = 100 pF connected to DV_DD/2, and V_REF = GND (unless otherwise noted)

PARAMETER			TEST CONDITIONS		MIN	TYP	MAX	UNIT
OFFSET VOLTAGE
Input offset voltage		V_OS	AV_DD = DV_DD = 5 V, V_REF = V_IN = AV_DD/2, V_CM = 2.5 V			±25	±100	μV
			AV_DD = DV_DD = 5 V, V_REF = V_IN = AV_DD/2, V_CM = 4.5 V			±75	±325	μV
	vs temperature, –40°C to 125°C	dV_OS/dT	AV_DD = DV_DD = 5 V, V_CM = 2.5 V	T_A = –40°C to 125°C		0.35	1.2	μV/°C
	vs temperature, –40°C to 85°C		AV_DD = DV_DD = 5 V, V_CM = 2.5 V			0.15	0.9	μV/°C
	vs temperature, –40°C to 125°C		AV_DD = DV_DD = 5 V, V_CM = 4.5 V	T_A = –40°C to 125°C		0.6	1.8	μV/°C
	vs temperature, –40°C to 85°C		AV_DD = DV_DD = 5 V, V_CM = 4.5 V			0.3	1.3	μV/°C
	vs power supply	PSRR	AV_DD = DV_DD = 2.2 V to 5.5 V, V_CM = 0.5 V, V_REF = V_IN = AV_DD/2			5	20	μV/V
	Over temperature, –40°C to 125°C		AV_DD = DV_DD = 2.2 V to 5.5 V, V_CM = 0.5 V, V_REF = V_IN = AV_DD/2	T_A = –40°C to 125°C		5	40	μV/V
INPUT ON-CHANNEL CURRENT
Input on-channel current (Ch0, Ch1)		I_IN	V_REF = V_IN = AV_DD/2			±1.5	±5	nA
	Over temperature, –40°C to 125°C		V_REF = V_IN = AV_DD/2		See Typical Characteristics			nA
INPUT VOLTAGE RANGE
Input voltage range⁽¹⁾		I_VR			GND – 0.1		AV_DD + 0.1	V
Overvoltage input range			No output phase reversal⁽²⁾		GND – 0.3		AV_DD + 0.3	V
INPUT IMPEDANCE (Channel On)⁽³⁾
Channel input capacitance		C_CH				2		pF
Channel switch resistance		R_SW				150		Ω
Amplifier input capacitance		C_AMP				3		pF
Amplifier input resistance		R_AMP	Input resistance to GND			10		GΩ
V_CAL/CH0		R_IN	CAL1 or CAL2 selected			100		kΩ
GAIN SELECTIONS
Nominal gains			Binary gains: 1, 2, 4, 8, 16, 32, 64, 128		1		128
			Scope gains: 1, 2, 5, 10, 20, 50, 100, 200		1		200
DC gain error		G = 1	V_OUT = GND + 85 mV to DV_DD – 85 mV			0.006%	0.1%
		1 < G ≤ 32	V_OUT = GND + 85 mV to DV_DD – 85 mV				0.1%
		G ≥ 50	V_OUT = GND + 85 mV to DV_DD – 85 mV				0.3%
DC gain drift		G = 1	V_OUT = GND + 85 mV to DV_DD – 85 mV	T_A = –40°C to 125°C		0.5		ppm/°C
		1 < G ≤ 32	V_OUT = GND + 85 mV to DV_DD – 85 mV	T_A = –40°C to 125°C		2		ppm/°C
		G ≥ 50	V_OUT = GND + 85 mV to DV_DD – 85 mV	T_A = –40°C to 125°C		6		ppm/°C
CAL2 DC gain error⁽⁴⁾			Op Amp + Input = 0.9 V_CAL, V_REF = V_CAL = AV_DD/2, G = 1			0.02%
CAL2 DC gain drift⁽⁴⁾			Op Amp + Input = 0.9 V_CAL, V_REF = V_CAL = AV_DD/2, G = 1	T_A = –40°C to 125°C		2		ppm/°C
CAL3 DC gain error⁽⁴⁾			Op Amp + Input = 0.1 V_CAL, V_REF = V_CAL = AV_DD/2, G = 1			0.02%
CAL3 DC gain drift⁽⁴⁾			Op Amp + Input = 0.1 V_CAL, V_REF = V_CAL = AV_DD/2, G = 1	T_A = –40°C to 125°C		2		ppm/°C
INPUT IMPEDANCE (CHANNEL OFF)⁽³⁾
Input impedance		C_CH	See Figure 55			2		pF
INPUT OFF-CHANNEL CURRENT
Input Off-Channel Current (Ch0, Ch1)⁽⁵⁾		I_LKG	V_REF = GND, V_OFF-CHANNEL = AV_DD/2, V_ON-CHANNEL = AV_DD/2 – 0.1 V			±0.05	±1	nA
	Over temperature, –40°C to 125°C		V_REF = GND, V_OFF-CHANNEL = AV_DD/2, V_ON-CHANNEL = AV_DD/2 – 0.1 V		See Typical Characteristics
Channel-to-Channel Crosstalk						130		dB
OUTPUT
Voltage output swing from rail			I_OUT = ±0.25 mA, AV_DD ≥ DV_DD⁽⁷⁾		GND + 0.05		DV_DD – 0.05	V
			I_OUT = ±5 mA, AV_DD ≥ DV_DD⁽⁷⁾		GND + 0.25		DV_DD – 0.25	V
DC output nonlinearity			V_OUT = GND + 85 mV to DV_DD – 85 mV⁽⁶⁾			0.0015		%FSR
Short circuit current		I_SC				–30/+60		mA
Capacitive load drive		C_LOAD			See Typical Characteristics
NOISE
Input voltage noise density		e_n	f > 10 kHz, C_L = 100 pF, V_S = 5 V			12		nV/√Hz
			f > 10 kHz, C_L = 100 pF, V_S = 2.2 V			22		nV/√Hz
Input voltage noise		e_n	f = 0.1 Hz to 10 Hz, C_L = 100 pF, V_S = 5 V			0.362		μV_PP
			f = 0.1 Hz to 10 Hz, C_L = 100 pF, V_S = 2.2 V			0.736		μV_PP
Input current density		I_n	f = 10 kHz, C_L = 100 pF			400		fA/√Hz
SLEW RATE
Slew rate		SR			See Table 1			V/μs
SETTLING TIME
Settling time		t_S			See Table 1			μs
FREQUENCY RESPONSE
Frequency response					See Table 1			MHz
THD + NOISE
			G = 1, f = 1 kHz, V_OUT = 4 V_PP at 2.5V_DC, C_L = 100 pF			0.003%
			G = 10, f = 1 kHz, V_OUT = 4 V_PP at 2.5V_DC, C_L = 100 pF			0.005%
			G = 50, f = 1 kHz, V_OUT = 4 V_PP at 2.5V_DC, C_L = 100 pF			0.03%
			G = 128, f = 1 kHz, V_OUT = 4 V_PP at 2.5V_DC, C_L = 100 pF			0.08%
			G = 200, f = 1 kHz, V_OUT = 4 V_PP at 2.5V_DC, C_L = 100 pF			0.1%
			G = 1, f = 20 kHz, V_OUT = 4 V_PP at 2.5V_DC, C_L = 100 pF			0.02%
			G = 10, f = 20 kHz, V_OUT = 4 V_PP at 2.5V_DC, C_L = 100 pF			0.01%
			G = 50, f = 20 kHz, V_OUT = 4 V_PP at 2.5V_DC, C_L = 100 pF			0.03%
			G = 128, f = 20 kHz, V_OUT = 4 V_PP at 2.5V_DC, C_L = 100 pF			0.08%
			G = 200, f = 20 kHz, V_OUT = 4 V_PP at 2.5V_DC, C_L = 100 pF			0.11%
POWER SUPPLY
Operating voltage range⁽⁷⁾		AV_DD			2.2		5.5	V
		DV_DD			2.2		5.5	V
Quiescent current analog		I_QA	I_O = 0, G = 1, V_OUT = V_REF			0.33	0.45	mA
	Over temperature, –40°C to 125°C			T_A = –40°C to 125°C			0.45	mA
Quiescent current digital⁽⁸⁾⁽⁹⁾⁽¹⁰⁾		I_QD	I_O = 0, G = 1, V_OUT = V_REF, SCLK at 10 MHz, CS = Logic 0, DIO or DIN = Logic 0			0.75	1.2	mA
	Over temperature, –40°C to 125°C⁽⁸⁾⁽⁹⁾⁽¹⁰⁾		I_O = 0, G = 1, V_OUT = V_REF, SCLK at 10 MHz, CS = Logic 0, DIO or DIN = Logic 0	T_A = –40°C to 125°C			1.2	mA
Shutdown current analog + digital⁽⁸⁾⁽⁹⁾		I_SDA + I_SDD	I_O = 0, V_OUT = V_REF, G = 1, SCLK Idle			4		μA
			I_O = 0, V_OUT = 0, G = 1, SCLK at 10MHz, CS = Logic 0, DIO or DIN = Logic 0			245		μA
POWER-ON RESET (POR)
POR trip voltage			Digital interface disabled and Command Register set to POR values for DV_DD < POR Trip Voltage			1.6		V
TEMPERATURE RANGE
Specified range					–40		125	°C
Operating range					–40		125	°C
Thermal resistance		θ_JA
	VSSOP-10					164		°C/W
DIGITAL INPUTS (SCLK, CS, DIO, DIN)
Logic low					0		0.3DV_DD	V
Input leakage current (SCLK and CS only)					–1		1	μA
Weak pulldown current (DIO, DIN only)						10		μA
Logic high					0.7DV_DD		DV_DD	V
Hysteresis						700		mV
DIGITAL OUTPUT (DIO, DOUT)
Logic high			I_OH = –3 mA (sourcing)		DV_DD – 0.4		DV_DD	V
Logic low			I_OL = 3 mA (sinking)		GND		GND + 0.4	V
CHANNEL AND GAIN TIMING
Channel select time						0.2		μs
Gain select time						0.2		μs
SHUTDOWN MODE TIMING
Enable time						4		μs
Disable time			V_OUT goes high-impedance, R_F and R_I remain connected between V_OUT and V_REF			2		μs
POWER-ON-RESET (POR) TIMING
POR power-up time			DV_DD ≥ 2 V			40		μs
POR power-down time			DV_DD ≤ 1.5 V			5		μs

(1) Gain error is a function of the input voltage. Gain error outside of the range (GND + 85 mV ≤ V_OUT ≤ DV_DD – 85 mV) increases to 0.5% (typical).

(2) Input voltages beyond this range must be current-limited to < |10 mA| through the input protection diodes on each channel to prevent permanent destruction of the device.

(3) See Figure 55.

(4) Total V_OUT error must be computed using input offset voltage error multiplied by gain. Includes op amp G = 1 error.

(5) Maximum specification limitation limited by final test time and capability.

(6) Measurement limited by noise in test equipment and test time.

(7) When AV_DD is less than DV_DD, the output is clamped to AV_DD + 300 mV.

(8) Does not include current into or out of the V_REF pin. Internal R_F and R_I are always connected between V_OUT and V_REF.

(9) Digital logic levels: DIO or DIN = logic 0. 10-μA internal pulldown current source.

(10) Includes current from op amp output structure.

7.6 SPI Timing: V_S = AV_DD = DV_DD = 2.2 V to 5 V

At T_A = +25°C, R_L = 10kΩ//C_L = 100pF connected to DV_DD/2, and V_REF = GND, unless otherwise noted.

			MIN	NOM	MAX	UNIT
	Input capacitance (SCLK, CS, and DIO pins)			1		pF
t_RFI	Input rise and fall time⁽¹⁾ (CS, SCLK, and DIO pins)				2	μs
t_RFO	Output rise and fall time (DIO pin)⁽¹⁾	C_LOAD = 60 pF			10	ns
t_CSH	CS high time (CS pin)⁽¹⁾		40			ns
t_CSO	SCLK edge to CS fall setup time⁽¹⁾		10			ns
t_CSSC	CS fall to first SCLK edge setup time		10			ns
f_SCLK	SCLK Frequency⁽²⁾				10	MHz
t_HI	SCLK high time⁽³⁾		40			ns
t_LO	SCLK low time⁽³⁾		40			ns
t_SCCS	SCLK last edge to CS rise setup time⁽¹⁾		10			ns
t_CS1	CS rise to SCLK edge setup time⁽¹⁾		10			ns
t_SU	DIN setup time		10			ns
t_HD	DIN hold time		10			ns
t_DO	SCLK to DOUT valid propagation delay⁽¹⁾				25	ns
t_SOZ	CS rise to DOUT forced to Hi-Z⁽¹⁾				20	ns

(1) Ensured by design; not production tested.

(2) When using devices in daisy-chain mode, the maximum clock frequency for SCLK is limited by SCLK rise and fall time, DIN setup time, and DOUT propagation delay. See Figure 61. Based on this limitation, the maximum SCLK frequency for daisy-chain mode is 9.09 MHz.

(3) t_HI and t_LO must not be less than 1/SCLK (maximum).

PGA112 PGA113 PGA116 PGA117 tim_spi_00_bos424.gif

Figure 1. SPI Mode 0, 0

PGA112 PGA113 PGA116 PGA117 tim_spi_11_bos424.gif

Figure 2. SPI Mode 1, 1

7.7 Typical Characteristics

at T_A = 25°C, AV_DD = DV_DD = 5 V, R_L = 10 kΩ connected to DV_DD/2, V_REF = GND, and C_L = 100 pF, unless otherwise noted.

PGA112 PGA113 PGA116 PGA117 tc_histo_vo_bos424.gif

Figure 3. Offset Voltage

PGA112 PGA113 PGA116 PGA117 tc_histo_vo_drift_85_bos424.gif

Figure 5. Offset Voltage Drift (–40°C to 85°C)

PGA112 PGA113 PGA116 PGA117 tc_histo_vo_drift_125_bos424.gif

Figure 7. Offset Voltage Drift (–40°C to 125°C)

PGA112 PGA113 PGA116 PGA117 tc_vio-vi_shade_bos424.gif

Figure 9. Input Offset Voltage vs Input Voltage

PGA112 PGA113 PGA116 PGA117 tc_histo_gerr_1g_bos424.gif

Figure 11. Gain Error (G = 1)

PGA112 PGA113 PGA116 PGA117 tc_histo_gerr_32g_bos424.gif

Figure 13. Gain Error (G ≥ 50)

PGA112 PGA113 PGA116 PGA117 tc_histo_gerr_drift_1g_bos424.gif

Figure 15. Gain Error Drift (–40°C to 125°C)

PGA112 PGA113 PGA116 PGA117 tc_histo_cal2_gerr_bos424.gif

Figure 17. CAL2 Gain Error

PGA112 PGA113 PGA116 PGA117 tc_histo_cal2_gerr_drift_bos424.gif

Figure 19. CAL2 Gain Error Drift (–40°C to 125°C)

PGA112 PGA113 PGA116 PGA117 tc_noise_vpp_bos424.gif

Figure 21. 0.1 Hz To 10 Hz NOISE

PGA112 PGA113 PGA116 PGA117 tc_spec_dens_bos424.gif

Figure 23. Spectral NOISE Density

PGA112 PGA113 PGA116 PGA117 tc_112_thdn-frq_4v_bos424.gif

Figure 25. PGA112, PGA116 THD + NOISE vs Frequency (V_OUT = 4 V_PP)

PGA112 PGA113 PGA116 PGA117 tc_113_thdn-frq_4v_bos424.gif

Figure 27. PGA113, PGA117 THD + Noise vs Frequency (V_OUT = 4 V_PP)

PGA112 PGA113 PGA116 PGA117 tc_iq-vs_bos424.gif

Figure 29. Total Quiescent Current vs Supply Voltage

PGA112 PGA113 PGA116 PGA117 tc_vout_iout_22v_bos424.gif

Figure 31. Output Voltage vs Output Current

PGA112 PGA113 PGA116 PGA117 tc_vo_swing-frq_22v_a_bos424.gif

Figure 33. PGA112, PGA116 Output Voltage Swing vs Frequency

PGA112 PGA113 PGA116 PGA117 tc_vo_swing-frq_a_bos424.gif

Figure 35. PGA112, PGA116 Output Voltage Swing vs Frequency

PGA112 PGA113 PGA116 PGA117 tc_vout_swing_fqcy_22v_glow_bos424.gif

Figure 37. PGA113, PGA117 Output Voltage Swing vs Frequency

PGA112 PGA113 PGA116 PGA117 tc_vout_swing_fqcy_55v_glow_bos424.gif

Figure 39. PGA113, PGA117 Output Voltage Swing vs Frequency

PGA112 PGA113 PGA116 PGA117 tc_ovrshoot_cload_bos424.gif

Figure 41. Small-Signal Overshoot vs Load Capacitance

PGA112 PGA113 PGA116 PGA117 tc_ib_on_temp_bos424.gif

Figure 43. Input ON-Channel Current vs Temperature

PGA112 PGA113 PGA116 PGA117 tc_psrr-frq_bos424.gif

Figure 45. Power-Supply Rejection Ratio vs Frequency

PGA112 PGA113 PGA116 PGA117 tc_sm_resp_1-20_bos424.gif

Figure 47. Small-Signal Pulse Response

PGA112 PGA113 PGA116 PGA117 tc_lg_resp_1-10_bos424.gif

Figure 49. Large-Signal Pulse Response

PGA112 PGA113 PGA116 PGA117 tc_pwr_up_dwn_bos424.gif

Figure 51. Power-Up and Power-Down Timing

PGA112 PGA113 PGA116 PGA117 tc_vo-shutdwn_bos424.gif

Figure 53. Output Voltage vs Shutdown Mode

PGA112 PGA113 PGA116 PGA117 tc_histo_vo_45v_bos424.gif

Figure 4. Offset Voltage

PGA112 PGA113 PGA116 PGA117 tc_histo_vo_drift_45v_85_bos424.gif

Figure 6. Offset Voltage Drift (–40°C to 85°C)

PGA112 PGA113 PGA116 PGA117 tc_histo_vo_drift_45v_125_bos424.gif

Figure 8. Offset Voltage Drift (–40°C to 125°C)

PGA112 PGA113 PGA116 PGA117 tc_112_116_nonlinear_bos424.gif

Figure 10. PGA112 and PGA116 Nonlinearity

PGA112 PGA113 PGA116 PGA117 tc_histo_gerr_2g_bos424.gif

Figure 12. Gain Error (1 < G ≤ 32)

PGA112 PGA113 PGA116 PGA117 tc_histo_gerr_128g_bos424.gif

Figure 14. Gain Error Drift (–40°C to 125°C)

PGA112 PGA113 PGA116 PGA117 tc_histo_gerr_drift_2g_bos424.gif

Figure 16. Gain Error Drift (–40°C to 125°C)

PGA112 PGA113 PGA116 PGA117 tc_histo_cal3_gerr_bos424.gif

Figure 18. CAL3 Gain Error

PGA112 PGA113 PGA116 PGA117 tc_histo_cal3_gerr_drift_bos424.gif

Figure 20. CAL3 Gain Error Drift (–40°C to 125°C)

PGA112 PGA113 PGA116 PGA117 tc_noise_vpp_5v_bos424.gif

Figure 22. 0.1 Hz to 10 Hz NOISE

PGA112 PGA113 PGA116 PGA117 tc_112_thdn-frq_2v_bos424.gif

Figure 24. PGA112, PGA116 THD + Noise vs Frequency (V_OUT = 2 V_PP)

PGA112 PGA113 PGA116 PGA117 tc_113_thdn-frq_2v_bos424.gif

Figure 26. PGA113, PGA117 THD + Noise vs Frequency (V_OUT = 2 V_PP)

PGA112 PGA113 PGA116 PGA117 tc_iq_tmp_bos424.gif

Figure 28. Quiescent Current vs Temperature

PGA112 PGA113 PGA116 PGA117 tc_shdn_iq-tmp_bos424.gif

Figure 30. Shutdown Quiescent Current vs Temperature

PGA112 PGA113 PGA116 PGA117 tc_vout_iout_5v_bos424.gif

Figure 32. Output Voltage vs Output Current

PGA112 PGA113 PGA116 PGA117 tc_vo_swing-frq_22v_b_bos424.gif

Figure 34. PGA112, PGA116 Output Voltage Swing vs Frequency

PGA112 PGA113 PGA116 PGA117 tc_vo_swing-frq_b_bos424.gif

Figure 36. PGA112, PGA116 Output Voltage Swing vs Frequency

PGA112 PGA113 PGA116 PGA117 tc_vout_swing_fqcy_22v_ghi_bos424.gif

Figure 38. PGA113, PGA117 Output Voltage Swing vs Frequency

PGA112 PGA113 PGA116 PGA117 tc_vout_swing_fqcy_55v_ghi_bos424.gif

Figure 40. PGA113, PGA117 Output Voltage Swing vs Frequency

PGA112 PGA113 PGA116 PGA117 tc_g-time_bos424.gif

Figure 42. Gain vs Settling Time

PGA112 PGA113 PGA116 PGA117 tc_ib_off_temp_bos424.gif

Figure 44. Input OFF-Channel Leakage Current vs Temperature

PGA112 PGA113 PGA116 PGA117 tc_xtalk-frq_bos424.gif

Figure 46. Crosstalk vs Frequency

PGA112 PGA113 PGA116 PGA117 tc_sm_resp_50-200_bos424.gif

Figure 48. Small-Signal Pulse Response

PGA112 PGA113 PGA116 PGA117 tc_lg_resp_50-200_bos424.gif

Figure 50. Large-Signal Pulse Response

PGA112 PGA113 PGA116 PGA117 tc_out_od_bos424.gif

Figure 52. Output Overdrive Performance

PGA112 PGA113 PGA116 PGA117 tc_hdwe_shutdown_bos424.gif

Figure 54. PGA116, PGA117 Hardware Shutdown Mode