SWRS112H Data sheet | 德州仪器 TI.com.cn

All measurements performed on CC1120EM_868_915 rev.1.0.1, CC1120EM_955 rev.1.2.1, CC1120EM_420_470 rev.1.0.1, or CC1120EM_169 rev.1.2.

Absolute Maximum Ratings

over operating free-air temperature range (unless otherwise noted)⁽¹⁾⁽²⁾

		MIN	MAX	UNIT
Supply voltage (VDD, AVDD_x)	All supply pins must have the same voltage	–0.3	3.9	V
Input RF level			+10	dBm
Voltage on any digital pin	Max 3.9 V	–0.3	VDD + 0.3	V
Voltage on analog pins (including DCPL pins)		–0.3	2.0	V
Storage temperature, T_stg		–40	125	°C

(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under general characteristics is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under recommended operating conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.

(2) All voltage values are with respect to V_SS unless otherwise noted.

4.1 ESD Ratings

				VALUE	UNIT
V_ESD	Electrostatic discharge (ESD) performance	Human body model (HBM), per ANSI/ESDA/JEDEC JS001⁽¹⁾		±2	kV
V_ESD	Electrostatic discharge (ESD) performance	Charged device model (CDM), per JESD22-C101⁽²⁾	All pins	±500	V

(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 HBM allows safe manufacturing with a standard ESD control process.

4.2 Recommended Operating Conditions (General Characteristics)

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

		MIN	MAX	UNIT
Voltage supply range	All supply pins must have the same voltage	2.0	3.6	V
Voltage on digital inputs		0	VDD	V
Ambient temperature range		–40	85	°C

4.3 RF Characteristics

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

PARAMETER	TEST CONDITIONS	MIN	TYP	MAX	UNIT
Frequency bands		820		960	MHz
		410		480
	See SWRA398, Using the CC112x/CC1175 at 274 to 320 MHz, for more information	(273.3)		(320)
		164		192
	Contact TI for more information about the use of these frequency bands	(205)		(240)
		(136.7)		(160)
Frequency resolution	In 820–950 MHz band		30		Hz
	In 410–480 MHz band		15
	In 164–192 MHz band		6
Data rate	Packet mode	0		200	kbps
Data rate	Transparent mode	0		100	kbps
Data rate step size			1e-4		bps

4.4 Power Consumption Summary

T_A = 25°C, VDD = 3.0 V if nothing else stated

PARAMETER		TEST CONDITIONS	TYP	MAX	UNIT
CURRENT CONSUMPTION: STATIC MODES
Power down with retention			0.12	1	µA
Power down with retention		Low-power RC oscillator running	0.5		µA
XOFF mode		Crystal oscillator / TCXO disabled	170		µA
IDLE mode		Clock running, system waiting with no radio activity	1.3		mA
CURRENT CONSUMPTION, TRANSMIT MODES
TX current consumption +10 dBm		950-MHz band (high-performance mode)	37		mA
TX current consumption 0 dBm		950-MHz band (high-performance mode)	26		mA
TX current consumption +14 dBm		868-, 915-, and 920-MHz bands (high-performance mode)	45		mA
TX current consumption +10 dBm		868-, 915-, and 920-MHz bands (high-performance mode)	34		mA
TX current consumption +15 dBm		434-MHz band (high-performance mode)	50		mA
TX current consumption +14 dBm			45		mA
TX current consumption +10 dBm			34		mA
TX current consumption +15 dBm		169-MHz band (high-performance mode)	54		mA
TX current consumption +14 dBm			49		mA
TX current consumption +10 dBm			41		mA
LOW-POWER MODE⁽¹⁾
TX current consumption +10 dBm			32		mA
CURRENT CONSUMPTION, RECEIVE MODE (HIGH-PERFORMANCE MODE)⁽¹⁾
RX wait for sync	1.2 kbps, 4-byte preamble	Using RX sniff mode, where the receiver wakes up at regular intervals to look for an incoming packet⁽²⁾	2		mA
RX wait for sync	38.4 kbps, 4-byte preamble		13.4		mA
RX peak current	433-, 868-, 915-, 920-, and 950–MHz bands	Peak current consumption during packet reception at the sensitivity threshold	22		mA
RX peak current	169-MHz band		23		mA
Average current consumption Check for data packet every 1 second using Wake on Radio		50 kbps, 5-byte preamble, 40-kHz RC oscillator used as sleep timer	15		µA
CURRENT CONSUMPTION, RECEIVE MODE (LOW-POWER MODE)⁽¹⁾
RX peak current Low-power RX mode	1.2 kbps	Peak current consumption during packet reception at the sensitivity level	17		mA

(1) T_A = 25°C, VDD = 3.0 V, f_c = 869.5 MHz if nothing else stated.

(2) See the sniff mode design note for more information (SWRA428).

4.5 Receive Parameters

All RX measurements made at the antenna connector, to a bit error rate (BER) limit of 1%.

PARAMETER		TEST CONDITIONS	MIN	TYP	MAX	UNIT
GENERAL RECEIVE PARAMETERS (HIGH-PERFORMANCE MODE)⁽¹⁾
Saturation				+10		dBm
Digital channel filter programmable bandwidth			8		200	kHz
IIP3, normal mode		At maximum gain		–14		dBm
IIP3, high linearity mode		Using 6-dB gain reduction in front end		–8		dBm
Data rate offset tolerance		With carrier sense detection enabled and assuming 4-byte preamble		±12%
Data rate offset tolerance		With carrier sense detection disabled		±0.2%
Spurious emissions	1–13 GHz (VCO leakage at 3.5 GHz)	Radiated emissions measured according to ETSI EN 300 220, f_c = 869.5 MHz		–56		dBm
Spurious emissions	30 MHz to 1 GHz			< –57		dBm
Optimum source impedance	868-, 915-, and 920-MHz bands	(Differential or single-ended RX configurations)		60 + j60 / 30 + j30		Ω
	433-MHz band			100 + j60 / 50 + j30
	169-MHz band			140 + j40 / 70 + j20
RX PERFORMANCE IN 950-MHZ BAND (HIGH-PERFORMANCE MODE)⁽²⁾
Sensitivity⁽³⁾		1.2 kbps, DEV = 4 kHz CHF = 10 kHz⁽⁴⁾		–120		dBm
		1.2 kbps, DEV = 20 kHz CHF = 50 kHz⁽⁴⁾		–114
		50 kbps 2GFSK, DEV = 25 kHz, CHF = 100 kHz⁽⁴⁾		–107
		200 kbps, DEV = 83 kHz (outer symbols), CHF = 200 kHz⁽⁴⁾, 4GFSK⁽⁵⁾		–100
Blocking and Selectivity	1.2 kbps 2FSK, 12.5-kHz channel separation, 4-kHz deviation, 10-kHz channel filter	± 12.5 kHz (adjacent channel)		51		dB
		± 25 kHz (alternate channel)		52
		± 1 MHz		73
		± 2 MHz		76
		± 10 MHz		81
	1.2 kbps 2FSK, 50-kHz channel separation, 20-kHz deviation, 50-kHz channel filter	± 50 kHz (adjacent channel)		47
		+ 100 kHz (alternate channel)		48
		± 1 MHz		69
		± 2 MHz		71
		± 10 MHz		78
	50 kbps 2GFSK, 200-kHz channel separation, 25-kHz deviation, 100-kHz channel filter (Same modulation format as 802.15.4g Mandatory Mode)	± 200 kHz (adjacent channel)		43
		± 400 kHz (alternate channel)		51
		± 1 MHz		62
		± 2 MHz		65
		± 10 MHz		71
	200 kbps 4GFSK, 83-kHz deviation (outer symbols), 200-kHz channel filter, zero IF	± 200 kHz (adjacent channel)		37
		± 400 kHz (alternate channel)		44
		± 1 MHz		55
		± 2 MHz		58
		± 10 MHz		64
RX PERFORMANCE IN 868-, 915-, AND 920-MHZ BANDS (HIGH-PERFORMANCE MODE)⁽²⁾
Sensitivity		300 bps with coding gain (using a PN spreading sequence with 4 chips per data bit) DEV = 4 kHz CHF = 10 kHz⁽⁴⁾		–127		dBm
		1.2 kbps, DEV = 4 kHz CHF = 10 kHz⁽⁴⁾		–123
		1.2 kbps, DEV = 10 kHz CHF = 42 kHz⁽⁴⁾		–120
		1.2 kbps, DEV = 20 kHz CHF = 50 kHz⁽⁴⁾		–117
		4.8 kbps OOK		–114
		38.4 kbps, DEV = 20 kHz CHF = 100 kHz⁽⁴⁾		–110
		50 kbps 2GFSK, DEV = 25 kHz, CHF = 100 kHz⁽⁴⁾		–110
		200 kbps, DEV = 83 kHz (outer symbols), CHF = 200 kHz⁽⁴⁾, 4GFSK		–103
Blocking and Selectivity	1.2-kbps 2-FSK, 12.5-kHz channel separation, 4-kHz deviation, 10-kHz channel filter	± 12.5 kHz (adjacent channel)		54		dB
		± 25 kHz (alternate channel)		54
		± 1 MHz		75
		± 2 MHz		79
		± 10 MHz		87
	1.2-kbps 2-FSK, 12.5-kHz channel separation, using settings optimized for blocking performance (3-kHz deviation, 7.8-kHz channel filter, minimum loop bandwidth)	± 1 kHz		78
		± 2 kHz		82
		± 8 MHz		88
		± 10 MHz		88
	1.2-kbps 2-FSK, 50-kHz channel separation, 20-kHz deviation, 50-kHz channel filter	± 50 kHz (adjacent channel)		48
		+ 100 kHz (alternate channel)		48
		± 1 MHz		69
		± 2 MHz		74
		± 10 MHz		81
	38.4-kbps 2-GFSK, 100-kHz channel separation, 20-kHz deviation, 100-kHz channel filter	+ 100 kHz (adjacent channel)		42
		± 200 kHz (alternate channel)		43
		± 1 MHz		62
		± 2 MHz		66
		± 10 MHz		74
	50-kbps 2-GFSK, 200-kHz channel separation, 25-kHz deviation, 100-kHz channel filter (Same modulation format as 802.15.4g Mandatory Mode)	± 200 kHz (adjacent channel)		43
		± 400 kHz (alternate channel)		50
		± 1 MHz		61
		± 2 MHz		65
		± 10 MHz		74
	200-kbps 4-GFSK, 83-kHz deviation (outer symbols), 200-kHz channel filter, zero IF	± 200 kHz (adjacent channel)		36
		± 400 kHz (alternate channel)		44
		± 1 MHz		55
		± 2 MHz		59
		± 10 MHz		67
Image rejection (image compensation enabled)		1.2 kbps, DEV = 4 kHz CHF = 10 kHz⁽⁴⁾, image at –125 kHz		54		dB
RX PERFORMANCE IN 434-MHZ BAND (HIGH-PERFORMANCE MODE)⁽²⁾
Sensitivity		1.2 kbps, DEV = 4 kHz CHF = 10 kHz⁽⁴⁾		–123		dBm
		50 kbps 2GFSK, DEV = 25 kHz, CHF = 100 kHz		–109
		1.2 kbps, DEV = 20 kHz CHF = 50 kHz⁽⁴⁾		–116
Blocking and Selectivity	1.2 kbps 2FSK, 12.5-kHz channel separation, 4-kHz deviation, 10-kHz channel filter	± 12.5 kHz (adjacent channel)		60		dB
		± 25 kHz (alternate channel)		60
		± 1 MHz		79
		± 2 MHz		82
		± 10 MHz		91
	1.2 kbps 2FSK, 50-kHz channel separation, 20-kHz deviation, 50-kHz channel filter	± 50 kHz (adjacent channel)		54
		+ 100 kHz (alternate channel)		54
		± 1 MHz		74
		± 2 MHz		78
		± 10 MHz		86
	38.4 kbps 2GFSK, 100-kHz channel separation, 20-kHz deviation, 100-kHz channel filter	+ 100 kHz (adjacent channel)		47
		± 200 kHz (alternate channel)		50
		± 1 MHz		67
		± 2 MHz		71
		± 10 MHz		78
RX PERFORMANCE IN 169-MHZ BAND (HIGH-PERFORMANCE MODE)⁽²⁾
Sensitivity		1.2 kbps, DEV = 4 kHz CHF = 10 kHz⁽⁴⁾		–123		dbm
Sensitivity		1.2 kbps, DEV = 20 kHz CHF = 50 kHz⁽⁴⁾		–117		dbm
Blocking and Selectivity	1.2 kbps 2FSK, 12.5-kHz channel separation, 4-kHz deviation, 10-kHz channel filter	± 12.5 kHz (adjacent channel)		64		dB
		± 25 kHz (alternate channel)		66
		± 1 MHz		82
		± 2 MHz		83
		± 10 MHz		89
	1.2 kbps 2FSK, 50-kHz channel separation, 20-kHz deviation, 50-kHz channel filter	± 50 kHz (adjacent channel)		60
		+ 100 kHz (alternate channel)		60
		± 1 MHz		76
		± 2 MHz		77
		± 10 MHz		83
Spurious response rejection	1.2 kbps 2FSK, 12.5-kHz channel separation, 4-kHz deviation, 10-kHz channel filter			70		dB
Image rejection (image compensation enabled)		1.2 kbps, DEV = 4 kHz CHF = 10 kHz⁽⁴⁾, image at –125 kHz		66		dB
RX PERFORMANCE IN LOW-POWER MODE⁽¹⁾
Sensitivity		1.2 kbps, DEV = 4 kHz CHF = 10 kHz⁽⁴⁾		–111		dBm
		38.4 kbps, DEV = 50 kHz CHF = 100 kHz⁽⁴⁾		–99
		50 kbps 2GFSK, DEV = 25 kHz, CHF = 100 kHz⁽⁴⁾		–99
Blocking and Selectivity	1.2 kbps 2FSK, 12.5-kHz channel separation, 4-kHz deviation, 10-kHz channel filter	± 12.5 kHz (adjacent channel)		46		dB
		± 25 kHz (alternate channel)		46
		± 1 MHz		73
		± 2 MHz		78
		± 10 MHz		79
	1.2 kbps 2FSK, 50-kHz channel separation, 20-kHz deviation, 50-kHz channel filter	± 50 kHz (adjacent channel)		43
		+ 100 kHz (alternate channel)		45
		± 1 MHz		71
		± 2 MHz		74
		± 10 MHz		75
	38.4 kbps 2GFSK, 100-kHz channel separation, 20-kHz deviation, 100-kHz channel filter	+ 100 kHz (adjacent channel)		37
		+ 200 kHz (alternate channel)		43
		± 1 MHz		58
		± 2 MHz		62
		+ 10 MHz		64
	50 kbps 2GFSK, 200-kHz channel separation, 25-kHz deviation, 100-kHz channel filter (Same modulation format as 802.15.4g Mandatory Mode)	+ 200 kHz (adjacent channel)		43
		+ 400 kHz (alternate channel)		52
		± 1 MHz		60
		± 2 MHz		64
		± 10 MHz		65
Saturation				+10		dBm

(1) T_A = 25°C, VDD = 3.0 V, f_c = 869.5 MHz if nothing else stated.

(2) T_A = 25°C, VDD = 3.0 V if nothing else stated.

(3) Sensitivity can be improved if the TX and RX matching networks are separated.

(4) DEV is short for deviation, CHF is short for Channel Filter Bandwidth

(5) BT = 0.5 is used in all GFSK measurements

4.6 Transmit Parameters

T_A = 25°C, VDD = 3.0 V, f_c = 869.5 MHz if nothing else stated

PARAMETER		TEST CONDITIONS	TYP	UNIT
Maximum output power		At 950 MHz	+12	dBm
		At 915- and 920-MHz	+14
		At 915- and 920-MHz with VDD = 3.6 V	+15
		At 868 MHz	+15
		At 868 MHz with VDD = 3.6 V	+16
		At 433 MHz	+15
		At 433 MHz with VDD = 3.6 V	+16
		At 169 MHz	+15
		At 169 MHz with VDD = 3.6 V	+16
Minimum output power		Within fine step size range	–11	dBm
Minimum output power		Within coarse step size range	–40	dBm
Output power step size		Within fine step size range	0.4	dB
Adjacent channel power		4-GFSK 9.6 kbps in 12.5-kHz channel, measured in 100-Hz bandwidth at 434 MHz (FCC Part 90 Mask D compliant)	–75	dBc
		4-GFSK 9.6 kbps in 12.5-kHz channel, measured in 8.75-kHz bandwidth (ETSI EN 300 220 compliant)	–58
		2-GFSK 2.4 kbps in 12.5-kHz channel, 1.2-kHz deviation	–61
Spurious emissions (not including harmonics)			<–60	dBm
Harmonics	2nd Harm, 169 MHz	Transmission at +14 dBm (or maximum allowed in applicable band where this is less than +14 dBm) using TI reference design Emissions measured according to ARIB T-96 in 950-MHz band, ETSI EN 300-220 in 170-, 433-, and 868-MHz bands and FCC part 15.247 in 450- and 915-MHz band Fourth harmonic in 915-MHz band will require extra filtering to meet FCC requirements if transmitting for long intervals (>50-ms periods)	–39	dBm
	3rd Harm, 169 MHz		–58
	2nd Harm, 433 MHz		–56
	3rd Harm, 433 MHz		–51
	2nd Harm, 450 MHz		–60
	3rd Harm, 450 MHz		–45
	2nd Harm, 868 MHz		–40
	3rd Harm, 868 MHz		–42
	2nd Harm, 915 MHz		56	dBµV/m
	3rd Harm, 915 MHz		52
	4th Harm, 915 MHz		60
	2nd Harm, 950 MHz		–58	dBm
	3rd Harm, 950 MHz		–42	dBm
Optimum load impedance	868-, 915-, and 920-MHz bands		35 + j35	Ω
	433 MHz band		55 + j25
	169 MHz band		80 + j0

4.7 PLL Parameters

T_A = 25°C, VDD = 3.0 V if nothing else stated

PARAMETER	TEST CONDITIONS	TYP	UNIT
HIGH-PERFORMANCE MODE
Phase noise in 950-MHz band	± 10 kHz offset	–99	dBc/Hz
	± 100 kHz offset	–99
	± 1 MHz offset	–123
Phase noise in 868-, 915-, 920-MHz bands	± 10 kHz offset	–99	dBc/Hz
	± 100 kHz offset	–100
	± 1 MHz offset	–122
Phase noise in 433-MHz band	± 10 kHz offset	–106	dBc/Hz
	± 100 kHz offset	–107
	± 1 MHz offset	–127
Phase noise in 169-MHz band	± 10 kHz offset	–111	dBc/Hz
	± 100 kHz offset	–116
	± 1 MHz offset	–135
LOW-POWER MODE⁽¹⁾
Phase noise in 950-MHz band	± 10 kHz offset	–90	dBc/Hz
	± 100 kHz offset	–92
	± 1 MHz offset	–124
Phase noise in 868-, 915-, 920-MHz bands	± 10 kHz offset	–95	dBc/Hz
	± 100 kHz offset	–95
	± 1 MHz offset	–124
Phase noise in 433-MHz band	± 10 kHz offset	–98	dBc/Hz
	± 100 kHz offset	–102
	± 1 MHz offset	–129
Phase noise in 169-MHz band	± 10 kHz offset	–106	dBc/Hz
	± 100 kHz offset	–110
	± 1 MHz offset	–136

(1) T_A = 25°C, VDD = 3.0 V, f_c = 869.5 MHz if nothing else stated

4.8 32-MHz Clock Input (TCXO)

T_A = 25°C, VDD = 3.0 V if nothing else stated

PARAMETER		TEST CONDITIONS	MIN	TYP	MAX	UNIT
Clock frequency			31.25	32	33.6	MHz
TCXO with CMOS output⁽¹⁾	High input voltage	TCXO with CMOS output directly coupled to pin EXT_OSC	1.4		VDD	V
TCXO with CMOS output⁽¹⁾	Low input voltage	TCXO with CMOS output directly coupled to pin EXT_OSC	0		0.6	V
Clipped sine output	Clock input amplitude (peak-to-peak)	TCXO clipped sine output connected to pin EXT_OSC through series capacitor	0.8		1.5	V

(1) For TCXO with CMOS output rise and fall time, see Section 4.15.

4.9 32-MHz Crystal Oscillator

T_A = 25°C, VDD = 3.0 V if nothing else stated

PARAMETER	TEST CONDITIONS	MIN	TYP	MAX	UNIT
Crystal frequency	It is expected that there be will degraded sensitivity at multiples of XOSC/2 in RX, and an increase in spurious emissions when the RF channel is close to multiples of XOSC in TX. We recommend that the RF channel is kept RX_BW/2 away from XOSC/2 in RX, and that the level of spurious emissions be evaluated if the RF channel is closer than 1 MHz to multiples of XOSC in TX.	31.25	32	33.6	MHz
Load capacitance (C_L)			10		pF
ESR	Simulated over operating conditions			60	Ω

4.10 32-kHz Clock Input

T_A = 25°C, VDD = 3.0 V if nothing else stated

PARAMETER	MIN	TYP	MAX	UNIT
Clock frequency		32		kHz
32-kHz clock input pin input high voltage	0.8 × VDD			V
32-kHz clock input pin input high voltage			0.2 × VDD	V

4.11 32-kHz RC Oscillator

T_A = 25°C, VDD = 3.0 V if nothing else stated

PARAMETER	TEST CONDITIONS	TYP	UNIT
Frequency	After calibration	32	kHz
Frequency accuracy after calibration	Relative to frequency reference (32-MHz crystal or TCXO)	±0.1%
Initial calibration time⁽¹⁾

(1) For Initial calibration time of the 32-kHz RC Oscillator, see Section 4.15.

4.12 I/O and Reset

T_A = 25°C, VDD = 3.0 V if nothing else stated

PARAMETER	TEST CONDITIONS	MIN	TYP	MAX	UNIT
Logic input high voltage		0.8 × VDD			V
Logic input low voltage				0.2 × VDD	V
Logic output high voltage	At 4-mA output load or less	0.8 × VDD			V
Logic output low voltage	At 4-mA output load or less			0.2 × VDD	V
Power-on reset threshold	Voltage on DVDD pin		1.3		V

4.13 Temperature Sensor

T_A = 25°C, VDD = 3.0 V if nothing else stated⁽¹⁾

PARAMETER	TEST CONDITIONS	MIN	TYP	MAX	UNIT
Temperature sensor range		–40		85	°C
Temperature coefficient	Change in sensor output voltage versus change in temperature		2.66		mV/°C
Typical output voltage	Typical sensor output voltage at T_A = 25°C, VDD = 3.0 V		794		mV
VDD coefficient	Change in sensor output voltage versus change in VDD		1.17		mV/V

(1) The CC1120 device can be configured to provide a voltage proportional to temperature on GPIO1. The temperature can be estimated by measuring this voltage (see Section 4.13, Temperature Sensor). For more information, refer to CC112X/CC120X On-Chip Temperature Sensor (SWRA415).

4.14 Thermal Resistance Characteristics for RHB Package

NAME	DESCRIPTION	°C/W⁽¹⁾
RΘ_JC(top)	Junction-to-case (top)	21.1
RΘ_JB	Junction-to-board	5.3
RΘ_JA	Junction-to-free air	31.3
Psi_JT	Junction-to-package top	0.2
Psi_JB	Junction-to-board	5.3
RΘ_JC(bot)	Junction-to-case (bottom)	0.8

(1) These values are based on a JEDEC-defined 2S2P system (with the exception of the Theta JC [RΘ_JC] value, which is based on a JEDEC-defined 1S0P system) and will change based on environment as well as application. For more information, see these EIA/JEDEC standards:

JESD51-2, Integrated Circuits Thermal Test Method Environmental Conditions - Natural Convection (Still Air)
JESD51-3, Low Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
JESD51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
JESD51-9, Test Boards for Area Array Surface Mount Package Thermal Measurements

Power dissipation of 40 mW and an ambient temperature of 25ºC is assumed.

4.15 Timing Requirements

T_A = 25°C, VDD = 3.0 V, f_c = 869.5 MHz if nothing else stated

PARAMETER		TEST CONDITIONS	NOM	MAX	UNIT
Power down to IDLE		Depends on crystal	0.4		ms
IDLE to RX/TX		Calibration disabled	166		µs
IDLE to RX/TX		Calibration enabled	461		µs
RX/TX turnaround			50		µs
RX/TX to IDLE time		Calibrate when leaving RX/TX enabled	296		µs
RX/TX to IDLE time		Calibrate when leaving RX/TX disabled	0		µs
Frequency synthesizer calibration		When using SCAL strobe	391		µs
Time from start RX until valid RSSI Including gain settling (function of channel bandwidth. Programmable for trade-off between speed and accuracy)		12.5-kHz channels	4.6		ms
		200-kHz channels	0.3		ms
32-MHz CLOCK INPUT (TCXO)⁽¹⁾
TCXO with CMOS output	Rise and fall time			2	ns
32-kHz RC OSCILLATOR⁽²⁾
Initial calibration time			1.6		ns

(1) See Section 4.8 for more information about the 32-MHz Clock Input (TCXO).

(2) See Section 4.11 for more information about the 32-kHz RC Oscillator.

4.16 Regulatory Standards

PERFORMANCE MODE	FREQUENCY BAND	SUITABLE FOR COMPLIANCE WITH
High-performance mode	820–960 MHz⁽¹⁾	ARIB T-96 ARIB T-108 ETSI EN 300 220 category 2 ETSI EN 54-25 FCC PART 101 FCC PART 24 SUBMASK D FCC PART 15.247 FCC PART 15.249 FCC PART 90 MASK G FCC PART 90 MASK J
	410–480 MHz⁽²⁾	ARIB T-67 ARIB RCR STD-30 ETSI EN 300 220 category 1 FCC PART 90 MASK D FCC PART 90 MASK G
	164–192 MHz⁽²⁾	ETSI EN 300 220 category 1 FCC PART 90 MASK D
Low-power mode	820–960 MHz	ETSI EN 300 220 category 2 FCC PART 15.247 FCC PART 15.249
	410–480 MHz	ETSI EN 300 220 category 2
	164–192 MHz	ETSI EN 300 220 category 2

(1) Performance also suitable for systems targeting maximum allowed output power in the respective bands, using a range extender such as the CC1190 device

(2) Performance also suitable for systems targeting maximum allowed output power in the respective bands, using a range extender