SNWS018 Data sheet | 德州仪器 TI.com.cn

6.1 Absolute Maximum Ratings

over operating free-air temperature range (unless otherwise noted)⁽¹⁾

	MIN	MAX	UNIT
SUPPLY VOLTAGE
VDD - GND		3.6	V
RF INPUT
Input power		10	dBm
DC voltage		400	mV
Enable input voltage	V_SS – 0.4 V < V_EN < V_DD + 0.4 V
Junction temperature⁽²⁾		150	°C
Maximum lead temperature (soldering, 10 seconds)		260	°C
Storage temperature, T_stg	–65	150	°C

(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.

(2) The maximum power dissipation is a function of T_J(MAX) , R_θJA. The maximum allowable power dissipation at any ambient temperature is P_D = (T_J(MAX) – T_A)/R_θJA. All numbers apply for packages soldered directly into a PC board.

6.2 ESD Ratings

			VALUE	UNIT
V_(ESD)	Electrostatic discharge	Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001⁽¹⁾	±2000	V
		Charged-device model (CDM), per JEDEC specification JESD22-C101⁽²⁾	±2000
		Machine model	±200

(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.

6.3 Recommended Operating Conditions

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

	MIN	MAX	UNIT
Supply voltage	2.7	3.3	V
Ambient temperature	–40	85	°C
RF frequency	50	3500	MHz
RF input power⁽¹⁾	–45	–5	dBm
RF input power⁽¹⁾	–58	–18	dBV

(1) Power in dBV = dBm + 13 when the impedance is 50 Ω.

6.4 Thermal Information

THERMAL METRIC⁽¹⁾		LVM221	UNIT
		NGF (WSON)
		6 PINS
R_θJA	Junction-to-ambient thermal resistance⁽²⁾	100.4	°C/W
R_θJC(top)	Junction-to-case (top) thermal resistance	120	°C/W
R_θJB	Junction-to-board thermal resistance	7	°C/W
ψ_JT	Junction-to-top characterization parameter	69.6	°C/W
ψ_JB	Junction-to-board characterization parameter	6.9	°C/W
R_θJC(bot)	Junction-to-case (bottom) thermal resistance	69.9	°C/W

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

(2) The maximum power dissipation is a function of T_J(MAX) , R_θJA. The maximum allowable power dissipation at any ambient temperature is P_D = (T_J(MAX) – T_A)/R_θJA. All numbers apply for packages soldered directly into a PC board.

6.5 2.7-V DC and AC Electrical Characteristics

Unless otherwise specified, all limits are ensured at T_A = 25°C, V_DD = 2.7 V, RF input frequency ƒ = 1855-MHz continuous wave (CW), modulated.⁽¹⁾

PARAMETER		TEST CONDITIONS	MIN⁽²⁾	TYP⁽³⁾	MAX⁽²⁾	UNIT
SUPPLY INTERFACE
I_DD	Supply current	Active mode: EN = high, no signal present at RF_IN	6.5	7.2	8.5	mA
		Active mode: EN = high, no signal present at RF_IN T_A = –40°C to 85°C	5		10	mA
		Shutdown: EN = low, no signal present at RF_IN		0.5	3	µA
		Shutdown: EN = low, no signal present at RF_IN T_A = –40°C to 85°C			4
		EN = Low: P_IN = 0 dBm⁽⁴⁾ T_A = –40°C to 85°C			10
LOGIC ENABLE INTERFACE
V_LOW	EN logic low input level (shutdown mode)	T_A = –40°C to 85°C			0.6	V
V_HIGH	EN logic high input level	T_A = –40°C to 85°C	1.1			V
I_EN	Current into EN pin	T_A = –40°C to 85°C			1	µA
RF INPUT INTERFACE
R_IN	Input resistance		40	47.1	60	Ω
OUTPUT INTERFACE
V_OUT	Output voltage swing	From positive rail, sourcing, V_REF = 0 V, I_OUT = 1 mA		16	40	mV
		From positive rail, sourcing, V_REF = 0 V, I_OUT = 1 mA T_A = –40°C to 85°C			50
		From negative rail, sinking, V_REF = 2.7 V, I_OUT = 1 mA		14	40
		From negative rail, sinking, V_REF = 2.7 V, I_OUT = 1 mA T_A = –40°C to 85°C			50
I_OUT	Output short circuit current	Sourcing, V_REF = 0 V, V_OUT = 2.6 V	3	5.4		mA
		Sourcing, V_REF = 0 V, V_OUT = 2.6 V T_A = –40°C to 85°C	2.7
		Sinking, V_REF = 2.7 V, V_OUT = 0.1 V	3	5.7
		Sinking, V_REF = 2.7 V, V_OUT = 0.1 V T_A = –40°C to 85°C	2.7
BW	Small signal bandwidth	No RF input signal. Measured from REF input current to V_OUT		450		kHz
R_TRANS	Output amplifier transimpedance gain	No RF input signal, from I_REF to V_OUT, DC	35	42.7	55	kΩ
SR	Slew rate	Positive, V_REF from 2.7 V to 0 V	3	4.1		V/µs
		Positive, V_REF from 2.7 V to 0 V T_A = –40°C to 85°C	2.7
		Negative, V_REF from 0 V to 2.7 V	3	4.2
		Negative, V_REF from 0 V to 2.7 V T_A = –40°C to 85°C	2.7
R_OUT	Output impedance⁽⁴⁾	No RF input signal, EN = High, DC measurement		0.6	5	Ω
R_OUT	Output impedance⁽⁴⁾	No RF input signal, EN = High, DC measurement T_A = –40°C to 85°C			6	Ω
I_OUT,SD	Output leakage current in shutdown mode	EN = Low, V_OUT = 2 V		21	300	nA
I_OUT,SD	Output leakage current in shutdown mode	EN = Low, V_OUT = 2 V T_A = –40°C to 85°C			500	nA
RF DETECTOR TRANSFER
V_OUT,MAX	Maximum output voltage⁽⁴⁾	ƒ = 50 MHz, P_IN= −5 dBm		1.76		V
		ƒ = 50 MHz, P_IN= −5 dBm T_A = –40°C to 85°	1.67		1.83
		ƒ = 900 MHz, P_IN= −5 dBm		1.75
		ƒ = 900 MHz, P_IN= −5 dBm T_A = –40°C to 85°C	1.67		1.82
		ƒ = 1855 MHz, P_IN= −5 dBm		1.61
		ƒ = 1855 MHz, P_IN= −5 dBm T_A = –40°C to 85°C	1.53		1.68
		ƒ = 2500 MHz, P_IN= −5 dBm		1.49
		ƒ = 2500 MHz, P_IN= −5 dBm T_A = –40°C to 85°C	1.42		1.57
		ƒ = 3000 MHz, P_IN= −5 dBm		1.4
		ƒ = 3000 MHz, P_IN= −5 dBm T_A = –40°C to 85°C	1.33		1.48
		ƒ = 3500 MHz, P_IN= −5 dBm		1.28
		ƒ = 3500 MHz, T_A = –40°C to 85°C	1.21		1.36
V_OUT,MIN	Minimum output voltage (pedestal)	No input signal	175	250	350	mV
	Minimum output voltage (pedestal)	No input signal, T_A = –40°C to 85°C	142		388
	Pedestal variation over temperature	No input signal, relative to 25°C T_A = –40°C to 85°C	–20		20
ΔV_OUT	Output voltage range⁽⁴⁾	ƒ = 50 MHz, P_IN from −45 dBm to −5 dBm		1.44		V
		ƒ = 50 MHz, P_IN from −45 dBm to −5 dBm T_A = –40°C to 85°C	1.37		1.52
		ƒ = 900 MHz, P_IN from −45 dBm to −5 dBm		1.4
		ƒ = 900 MHz, P_IN from −45 dBm to −5 dBm T_A = –40°C to 85°C	1.34		1.47
		ƒ = 1855 MHz, P_IN from −45 dBm to −5 dBm		1.3
		ƒ = 1855 MHz, P_IN from −45 dBm to −5 dBm T_A = –40°C to +85°C	1.24		1.37
		ƒ = 2500 MHz, P_IN from −45 dBm to −5 dBm		1.2
		ƒ = 2500 MHz, P_IN from −45 dBm to −5 dBm T_A = –40°C to 85°C	1.14		1.3
		ƒ = 3000 MHz, P_IN from −45 dBm to −5 dBm		1.12
		ƒ = 3000 MHz, P_IN from −45 dBm to −5 dBm T_A = –40°C to 85°C	1.07		1.2
		ƒ = 3500 MHz, P_IN from −45 dBm to −5 dBm		1.01
		ƒ = 3500 MHz, P_IN from −45 dBm to −5 dBm T_A = –40°C to 85°C	0.96		1.09
K_SLOPE	Logarithmic slope⁽⁴⁾	ƒ = 50 MHz	39	40.5	42	mV/dB
		ƒ = 900 MHz	36.7	38.5	40
		ƒ = 1855 MHz	34.4	35.7	37.1
		ƒ = 2500 MHz	32.6	33.8	35.2
		ƒ = 3000 MHz	31	32.5	34
		ƒ = 3500 MHz	30	31.9	33.5
P_INT	Logarithmic intercept⁽⁴⁾	ƒ = 50 MHz	–50.4	−49.4	–48.3	dBm
		ƒ = 900 MHz	–54.1	−52.8	–51.6
		ƒ = 1855 MHz	–53.2	−51.7	–50.2
		ƒ = 2500 MHz	–51.8	−50	–48.3
		ƒ = 3000 MHz	–51.1	−48.9	–46.6
		ƒ = 3500 MHz	–49.6	−46.8	–44.1
e_n	Output referred noise⁽⁵⁾	P_IN = −10 dBm at 10 kHz		1.5		µV/√Hz
v_N	Output referred noise⁽⁴⁾	Integrated over frequency band, 1 kHz to 6.5 kHz		100		µV_RMS
v_N	Output referred noise⁽⁴⁾	Integrated over frequency band, 1 kHz to 6.5 kHz T_A = –40°C to 85°C			150	µV_RMS
PSRR	Power supply rejection ratio⁽⁵⁾	P_IN = −10 dBm, ƒ = 1800 MHz		60		dB
PSRR	Power supply rejection ratio⁽⁵⁾	P_IN = −10 dBm, ƒ = 1800 MHz T_A = –40°C to 85°C	55			dB
POWER MEASUREMENT PERFORMANCE
E_LC	Log conformance error⁽⁴⁾	ƒ = 50 MHz −40 dBm ≤ P_IN ≤ −10 dBm	–0.6		0.56	dB
		ƒ = 50 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–1.1	0.53	1.3
		ƒ = 900 MHz −40 dBm ≤ P_IN ≤ −10 dBm	–0.7		0.37
		ƒ = 900 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–1.24	0.46	1.1
		ƒ = 1855 MHz −40 dBm ≤ P_IN ≤ −10 dBm	–0.4		0.24
		ƒ = 1855 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–1.1	0.48	1.1
		ƒ = 2500 MHz −40 dBm ≤ P_IN ≤ −10 dBm	–0.43		0.56
		ƒ = 2500 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–1	0.51	1.1
		ƒ = 3000 MHz −40 dBm ≤ P_IN ≤ −10 dBm	–0.87		1.34
		ƒ = 3000 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–1.2	0.56	1.6
		ƒ = 3500 MHz −40 dBm ≤ P_IN ≤ −10 dBm	–1.73		2.72
		ƒ = 3500 MHz, T_A = –40°C to 85°C	–2	0.84	2.7
E_VOT	Variation over temperature⁽⁴⁾	ƒ = 50 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–1.1	0.4	1.4	dB
		ƒ = 900 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–1	0.38	1.27
		ƒ = 1855 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–1.1	0.44	1.31
		ƒ = 2500 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–1.1	0.48	1.15
		ƒ = 3000 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–1.2	0.5	0.98
		ƒ = 3500 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–1.2	0.62	0.85
E_{1 dB}	Measurement error for a 1-dB Input power step⁽⁴⁾	ƒ = 50 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.06		0.069	dB
		ƒ = 900 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.056		0.056
		ƒ = 1855 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.069		0.069
		ƒ = 2500 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.084		0.084
		ƒ = 3000 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.092		0.092
		ƒ = 3500 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.1		0.1
E_{10 dB}	Measurement Error for a 10-dB Input power step ⁽⁴⁾	ƒ = 50 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.65		0.57	dB
		ƒ = 900 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.75		0.58
		ƒ = 1855 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.88		0.72
		ƒ = 2500 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.86		0.75
		ƒ = 3000 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.85		0.77
		ƒ = 3500 MHz, T_A = –40°C to 85°C −40 dBm ≤ P_IN ≤ −10 dBm	–0.76		0.74
S_T	Temperature sensitivity	ƒ = 50 MHz, −40 dBm ≤ P_IN ≤ −10 dBm		–7		mdB/°C
		ƒ = 50 MHz, −40°C < T_A < 25°C ⁽⁴⁾	–15		1
		ƒ = 900 MHz,−40 dBm ≤ P_IN ≤ −10 dBm		–6
		ƒ = 900 MHz, −40°C < T_A < 25°C −40 dBm ≤ P_IN ≤ −10 dBm⁽⁴⁾	–13.4		1.5
		ƒ = 1855 MHz, −40 dBm ≤ P_IN ≤ −10 dBm		–5.9
		ƒ = 1855 MHz, −40°C < T_A < 25°C −40 dBm ≤ P_IN ≤ −10 dBm⁽⁴⁾	–14.1		2.3
		ƒ = 2500 MHz,−40 dBm ≤ P_IN ≤ −10 dBm		–4.1
		ƒ = 2500 MHz, −40°C < T_A < 25°C −40 dBm ≤ P_IN ≤ −10 dBm⁽⁴⁾	–13.4		5.2
		ƒ = 3000 MHz, −40 dBm ≤ P_IN ≤ −10 dBm		–1.8
		ƒ = 3000 MHz, −40°C < T_A < 25°C −40 dBm ≤ P_IN ≤ −10 dBm⁽⁴⁾	–11.7		8
		ƒ = 3500 MHz, −40 dBm ≤ P_IN ≤ −10 dBm		0.5
		ƒ = 3500 MHz, −40°C < T_A < 25°C −40 dBm ≤ P_IN ≤ −10 dBm⁽⁴⁾	–10.5		1.2
S_T	Temperature sensitivity	ƒ = 50 MHz, −40 dBm ≤ P_IN ≤ −10 dBm		–6.7		mdB/°C
		ƒ = 50 MHz, 25°C < T_A < 85°C −40 dBm ≤ P_IN ≤ −10 dBm⁽⁴⁾	–12.3		–1.1
		ƒ = 900 MHz, −40 dBm ≤ P_IN ≤ −10 dBm		–6.7
		ƒ = 900 MHz, 25°C < T_A < 85°C −40 dBm ≤ P_IN ≤ −10 dBm⁽⁴⁾	–13.1		–0.2
		ƒ =1855 MHz, −40 dBm ≤ P_IN ≤ −10 dBm		–7.1
		ƒ =1855 MHz, 25°C < T_A < 85°C −40 dBm ≤ P_IN ≤ −10 dBm⁽⁴⁾	–14.7		0.42
		ƒ = 2500 MHz,−40 dBm ≤ P_IN ≤ −10 dBm		–7.6
		ƒ = 2500 MHz, 25°C < T_A < 85°C −40 dBm ≤ P_IN ≤ −10 dBm⁽⁴⁾	–15.9		0.63
		ƒ = 3000 MHz, −40 dBm ≤ P_IN ≤ −10 dBm		–8.5
		ƒ = 3000 MHz, 25°C < T_A < 85°C −40 dBm ≤ P_IN ≤ −10 dBm⁽⁴⁾	–18		1
		ƒ = 3500 MHz, −40 dBm ≤ P_IN ≤ −10 dBm		–9.5
		ƒ = 3500 MHz, 25°C < T_A < 85°C −40 dBm ≤ P_IN ≤ −10 dBm ⁽⁴⁾	–21.2		2.5
S_T	Temperature sensitivity⁽⁴⁾	ƒ = 50 MHz, P_IN = −10 dBm		–8.3		mdB/°C
		ƒ = 50 MHz, –40°C < T_A < 25°C P_IN = −10 dBm⁽⁴⁾	–15.8		–0.75
		ƒ = 900 MHz, P_IN = −10 dBm		–6
		ƒ = 900 MHz, –40°C < T_A < 25°C P_IN = −10 dBm⁽⁴⁾	–14.2		2.2
		ƒ = 1855 MHz, P_IN = −10 dBm		–7.4
		ƒ = 1855 MHz, –40°C < T_A < 25°C P_IN = −10 dBm⁽⁴⁾	–14.9		2
		ƒ = 2500 MHz, P_IN = −10 dBm		–6.6
		ƒ = 2500 MHz, –40°C < T_A < 25°C P_IN = −10 dBm⁽⁴⁾	–14.5		1.3
		ƒ = 3000 MHz, P_IN = −10 dBm		–4.9
		ƒ = 3000 MHz, –40°C < T_A < 25°C P_IN = −10 dBm⁽⁴⁾	–13		3.3
		ƒ = 3500 MHz, P_IN = −10 dBm		–3.4
		ƒ = 3500 MHz, –40°C < T_A < 25°C P_IN = −10 dBm⁽⁴⁾	–12		5.3
S_T	Temperature sensitivity⁽⁴⁾	ƒ = 50 MHz, P_IN = −10 dBm		–8.9		mdB/°C
		ƒ = 50 MHz, 25°C < T_A < 85°C P_IN = −10 dBm⁽⁴⁾	–12.4		–5.3
		ƒ = 900 MHz, P_IN = −10 dBm		–9.4
		ƒ = 900 MHz, 25°C < T_A < 85°C P_IN = −10 dBm⁽⁴⁾	–13.7		–5
		ƒ = 1855 MHz, P_IN = −10 dBm		–10
		ƒ = 1855 MHz, 25°C < T_A < 85°C P_IN = −10 dBm⁽⁴⁾	–14.6		–5.6
		ƒ = 2500 MHz, P_IN = −10 dBm		–10.8
		ƒ = 2500 MHz, 25°C < T_A < 85°C P_IN = −10 dBm⁽⁴⁾	–15.2		–6.5
		ƒ = 3000 MHz, P_IN = −10 dBm		–12.2
		ƒ = 3000 MHz, 25°C < T_A < 85°C P_IN = −10 dBm⁽⁴⁾	–16.5		–7.9
		ƒ = 3500 MHz, P_IN = −10 dBm		–13.5
		ƒ = 3500 MHz, 25°C < T_A < 85°C P_IN = −10 dBm⁽⁴⁾	–18.1		–9
P_MAX	Maximum input power for E_LC = 1 dB⁽⁴⁾	ƒ = 50 MHz		–5.9		dBm
		ƒ = 50 MHz, T_A = –40°C to 85°C	–8.85
		ƒ = 900 MHz		–6.1
		ƒ = 900 MHz, MIN at T_A = –40°C to 85°C	–9.3
		ƒ = 1855 MHz		–5.5
		ƒ = 1855 MHz, T_A = –40°C to 85°C	–8.3
		ƒ = 2500 MHz		–4.2
		ƒ = 2500 MHz, T_A = –40°C to 85°C	–6
		ƒ = 3000 MHz		–3.7
		ƒ = 3000 MHz, T_A = –40°C to 85°C	–5.4
		ƒ = 3500 MHz		–2.7
		ƒ = 3500 MHz, T_A = –40°C to 85°C	–7.2
P_MIN	Minimum input power for E_LC = 1 dB⁽⁴⁾	ƒ = 50 MHz		–40.3		dBm
		ƒ = 50 MHz, T_A = –40°C to 85°C			–38.9
		ƒ = 900 MHz		–44.2
		ƒ = 900 MHz, MIN at T_A = –40°C to 85°C			–42.9
		ƒ = 1855 MHz		–42.9
		ƒ = 1855 MHz, T_A = –40°C to 85°C			–41.2
		ƒ = 2500 MHz		–40.4
		ƒ = 2500 MHz, T_A = –40°C to 85°C			–38.6
		ƒ = 3000 MHz		–38.4
		ƒ = 3000 MHz, T_A = –40°C to 85°C			–35.8
		ƒ = 3500 MHz		–35.3
		ƒ = 3500 MHz, T_A = –40°C to 85°C			–31.9
DR	Dynamic range for E_LC = 1 dB⁽⁴⁾	ƒ = 50 MHz		34.5		dB
		ƒ = 50 MHz, T_A = –40°C to 85°C	31.5
		ƒ = 900 MHz		38.1
		ƒ = 900 MHz, MIN at T_A = –40°C to 85°C	34.4
		ƒ = 1855 MHz		37.4
		ƒ = 1855 MHz, T_A = –40°C to 85°C	34
		ƒ = 2500 MHz		36.1
		ƒ = 2500 MHz, T_A = –40°C to 85°C	33.8
		ƒ = 3000 MHz		34.8
		ƒ = 3000 MHz, T_A = –40°C to 85°C	32.4
		ƒ = 3500 MHz		32.7
		ƒ = 3500 MHz, T_A = –40°C to 85°C	26.2

(1) 2.7-V DC and AC Electrical Characteristics values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very limited self-heating of the device such that T_J = T_A. No specification of parametric performance is indicated in the electrical tables under conditions of internal self-heating where T_J > T_A.

(2) All limits are ensured by test or statistical analysis.

(3) Typical values represent the most likely parametric norm as determined at the time of characterization. Actual typical values may vary over time and also depend on the application and configuration. The typical values are not tested and are not specified on shipped production material.

(4) All limits are ensured by design and measurements which are performed on a limited number of samples. Limits represent the mean ±3–sigma values. The typical value represents the statistical mean value.

(5) This parameter is ensured by design and/or characterization and is not tested in production.

6.6 Timing Requirements

		NOM	MAX	UNIT
t_ON	Turnon time, no signal at P_IN, low-high transition EN, V_OUT to 90%⁽¹⁾	8	10	µs
t_ON	Turnon time, no signal at P_IN, low-high transition EN, V_OUT to 90%⁽¹⁾ T_A = –40°C to 85°C		12	µs
t_R	Rise time⁽²⁾, P_IN = no signal to 0 dBm, V_OUT from 10% to 90%	2		µs
t_R	Rise time⁽²⁾, P_IN = no signal to 0 dBm, V_OUT from 10% to 90% T_A = –40°C to 85°C		12	µs
t_F	Fall time⁽²⁾, P_IN = no signal to 0 dBm, V_OUT from 90% to 10%	2		µs
t_F	Fall time⁽²⁾, P_IN = no signal to 0 dBm, V_OUT from 90% to 10% T_A = –40°C to 85°C		12	µs

(1) All limits are ensured by design and measurements, which are performed on a limited number of samples. Limits represent the mean ±3-sigma values. The typical value represents the statistical mean value.

(2) This parameter is ensured by design and/or characterization and is not tested in production.

6.7 Typical Characteristics

Unless otherwise specified, V_DD = 2.7V, T_A = 25°C, measured on a limited number of samples.

Figure 1. Supply Current vs Supply Voltage

Figure 3. Output Voltage vs RF Input Power

Figure 5. Log Intercept vs Frequency

50 MHz

Figure 7. Mean Output Voltage and Log Conformance Error vs RF Input Power

1855 MHz

Figure 9. Mean Output Voltage and Log Conformance Error vs RF Input Power

3000 MHz

Figure 11. Mean Output Voltage and Log Conformance Error vs RF Input Power

50 MHz

Figure 13. Log Conformance Error (Mean ±3 Sigma) vs RF Input Power

1855 MHz

Figure 15. Log Conformance Error (Mean ±3 Sigma) vs RF Input Power

3000 MHz

Figure 17. Log Conformance Error (Mean ±3 Sigma) vs RF Input Power

50 MHz

Figure 19. Mean Temperature Drift Error vs Rf Input Power At 50 MHz

1855 MHz

Figure 21. Mean Temperature Drift Error vs RF Input Power

3000 MHz

Figure 23. Mean Temperature Drift Error vs RF Input Power

50 MHz

Figure 25. Temperature Drift Error (Mean ±3 Sigma) vs RF Input Power

1855 MHz

Figure 27. Temperature Drift Error (Mean ±3 Sigma) vs RF Input Power

3000 MHz

Figure 29. Temperature Drift Error (Mean ±3 Sigma) vs RF Input Power

50 MHz

Figure 31. Error For 1-dB Input Power Step vs RF Input Power

1855 MHz

Figure 33. Error For 1-dB Input Power Step vs RF Input Power

3000 MHz

Figure 35. Error For 1-dB Input Power Step vs RFInput Power

50 MHz

Figure 37. Error For 10-dB Input Power Step vs RF Input Power

1855 MHz

Figure 39. Error For 10-dB Input Power Step vs RF Input Power

3000 MHz

Figure 41. Error For 10-dB Input Power Step vs RF Input Power

50 MHz

Figure 43. Mean Temperature Sensitivity vs RF Input Power

1855 MHz

Figure 45. Mean Temperature Sensitivity vs RF Input Power

3000 MHz

Figure 47. Mean Temperature Sensitivity vs RF Input Power

50 MHz

Figure 49. Temperature Sensitivity (Mean ±3 Sigma) vs RF Input Power

1855 MHz

Figure 51. Temperature Sensitivity (Mean ±3 Sigma) vs RF Input Power

3000 MHz

Figure 53. Temperature Sensitivity (Mean ±3 Sigma) vs RF Input Power

900 MHz

Figure 55. Output Voltage and Log Conformance Error vs RR Input Power for Various Modulation Types

Figure 57. RF Input Impedance vs Frequency (Resistance and Reactance)

Figure 59. Power Supply Rejection Ratio vs Frequency

Figure 61. Sourcing Output Current vs Output Voltage

Figure 63. Output Voltage vs Sourcing Current

Figure 2. Supply Current vs Enable Voltage

Figure 4. Log Slope vs Frequency

Figure 6. Output Voltage vs Frequency

900 MHz

Figure 8. Mean Output Voltage and Log Conformance Error vs RF Input Power

2500 MHz

Figure 10. Mean Output Voltage and Log Conformance Error vs RF Input Power

3500 MHz

Figure 12. Mean Output Voltage and Log Conformance Error vs RF Input Power

900 MHz

Figure 14. Log Conformance Error (Mean ±3 Sigma) vs RF Input Powert

2500 MHz

Figure 16. Log Conformance Error (Mean ±3 Sigma) vs RF Input Power

3500 MHz

Figure 18. Log Conformance Error (Mean ±3 Sigma) vs RF Input Power

900 MHz

Figure 20. Mean Temperature Drift Error vs RF Input Power

2500 MHz

Figure 22. Mean Temperature Drift Error vs RF Input Powert

3500 MHz

Figure 24. Mean Temperature Drift Error vs RF Input Power

900 MHz

Figure 26. Temperature Drift Error (Mean ±3 Sigma) vs RF Input Power

2500 MHz

Figure 28. Temperature Drift Error (Mean ±3 Sigma) vs RF Input Power

3500 MHz

Figure 30. Temperature Drift Error (Mean ±3 Sigma) vs RF Input Power

900 MHz

Figure 32. Error For 1-dB Input Power Step vs RF Input Power

2500 MHz

Figure 34. Error For 1-dB Input Power Step vs RF Input Power

3500 MHz

Figure 36. Error For 1-dB Input Power Step vs RF Input Power

900 MHz

Figure 38. Error For 10-dB Input Power Step vs RF Input Power

2500 MHz

Figure 40. Error For 10-dB Input Power Step vs RF Input Power

3500 MHz

Figure 42. Error For 10-dB Input Power Step vs RF Input Power

900 MHz

Figure 44. Mean Temperature Sensitivity vs RF Input Power

2500 MHz

Figure 46. Mean Temperature Sensitivity vs RF Input Power

3500 MHz

Figure 48. Mean Temperature Sensitivity vs RF Input Power

900 MHz

Figure 50. Temperature Sensitivity (Mean ±3 Sigma) vs RF Input Power

2500 MHz

Figure 52. Temperature Sensitivity (Mean ±3 Sigma) vs RF Input Power

3500 MHz

Figure 54. Temperature Sensitivity (Mean ±3 Sigma) vs RF Input Power

1855 MHz

Figure 56. Output Voltage and Log Conformance Error vs RF Input Power for Various Modulation Types

Figure 58. Output Noise Spectrum vs Frequency

Figure 60. Output Amplifier Gain and Phase vs Frequency

Figure 62. Sinking Output Current vs Output Voltage

Figure 64. Output Voltage vs Sinking Current

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6 Specifications

6.1 Absolute Maximum Ratings

6.2 ESD Ratings

6.3 Recommended Operating Conditions

6.4 Thermal Information

6.5 2.7-V DC and AC Electrical Characteristics

6.6 Timing Requirements

6.7 Typical Characteristics