AD AD6190ARS

a
900 MHz RF Transceiver
AD6190
The receiver section includes a Low Noise Amplifier (LNA).
The LNA’s output drives an image-reject mixer; the mixer’s
output optimized for 10.7 MHz is filtered and processed by the
limiting IF amplifier.
FEATURES
Complete 900 MHz RF Transceiver
LNA
Receive Mixer
Transmit Mixer
Driver Amplifier
VCO
Prescaler
Limiter Amplifier with RSSI
On-Chip Low Dropout Regulator
Independent Sleep Modes for TX, RX
28-Lead SSOP Package
The transmit section accepts a modulated 10.7 MHz IF input,
and uses an image-reject upconverter to mix the signal up to the
902 MHz–928 MHz RF carrier frequency while suppressing the
unwanted image and LO components. The RF output is raised
to a nominal 0.5 milliwatt (–3 dBm) output level. This output
can be used directly or can drive an external power amplifier to
higher levels.
The on-chip VCO operates at 2× the local oscillator frequency.
This reduces oscillator pulling due to strong interferers in-band
or transmitter leakage. An on-chip 64/65 prescaler allows the
VCO to be controlled by a low cost 15 MHz CMOS synthesizer.
APPLICATIONS
902 MHz–928 MHz ISM Band Cordless Telephones
902 MHz–928 MHz ISM Band Wireless Data Systems
An on-chip low dropout regulator minimizes VCO pushing. The
transmit section, receive section, or both, can be placed in a low
current SLEEP mode when not in use. The AD6190 900 MHz
RF transceiver is packaged in a 28-lead SSOP package.
GENERAL DESCRIPTION
The AD6190 900 MHz RF Transceiver provides a complete
RF/IF section for systems operating in the 902 MHz–928 MHz
license-free ISM band. The high level of integration allows several
dozen discrete components to be replaced. It is ideally suited
for use in cordless telephone and wireless data applications.
The AD6190 900 MHz RF Transceiver is part of the Analog
Devices/Zilog “A-to-Z Phone” Spread-Spectrum System for
cordless telephone and data communications applications. Contact Zilog directly at (408) 370-8000 for more information on
the Z87000 series baseband controller chips.
FUNCTIONAL BLOCK DIAGRAM
10.7
10.7
RSSI
0
90
ANT
FILTER
LIMOUT
VREG
AD6190
T/R
S/W
TXON
VCO
POWER
MANAGEMENT
AND
CONTROL
/2
PA
I
Q
RXON
VCOON
Z87L00
SPREADSPECTRUM
CONTROLLER
VBATT
64/65
VOLTAGE
REGULATOR
VREG
0
90
10.7
15MHz SYNTHESIZER
REV. 0
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700
World Wide Web Site: http://www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 1998
(@ TA = +258C, VCC = +3.3 V, FIF = 10.7 MHz, FRF = 902 MHz–928 MHz, TX IF Input
AD6190–SPECIFICATIONS level 137 mV p-p, unless otherwise noted)
Parameter
RECEIVE RF SECTION
(LNA to Mixer Output)
Power Gain
Noise Figure
1 dB Compression (Input)
Input IP3
Image Rejection
TRANSMIT UPCONVERTER
Image Rejection
LO Feedthrough
Conditions
Min
Typ
FRF = 915 MHz, FLO = 904.3 MHz
28
24
4.2
–30
–17
33
dB
dB
dBm
dBm
dBc
FIF = 10.7 MHz, FLO = 904.3 MHz
FIF = 10.7 MHz, FLO = 904.3 MHz
35
48
–33
dBc
dBm
–3
+4.5
dBm
dBm
For IF Input Level = 137 mV p-p
VCO
Operating Frequency
(LO Frequency ×2)
IF LIMITER AMPLIFIER
First Stage Gain
Second Stage Gain
AC Output Level
DC Level
IF Port Impedance
RSSI OUTPUT
Slope
Output Voltage
Linear Range
RSSI Log Conformance Error
Units
Source Z = 50 Ω, IF Load Z = 330 Ω
DRIVER AMPLIFIER
Nominal Output Power
1 dB Compression
PRESCALER
Division Ratio
PREMOD = “1”
PREMOD = “0”
Output Level
Max
0
1783
RL = 2.2 k, CL < 10 pF
0.55
RL > 30 kΩ, CL < 30 pF
FIF = 10.7 MHz
With 10 Ω in Series with VCCIF
@ –100 dBm RF Input
@ –30 dBm RF Input
(With Respect to RF Input Level)
SUPPLY CURRENT
Transmit Mode
Receive Mode
Sleep Mode
(VCC = 3.3 V)
TXON, VCOON = 1; RXON = 0
RXON, VCOON = 1; TXON = 0
TXON, VCOON, RXON = 0
SUPPLY VOLTAGE
Other Supplies
VBATT
VCCTX, VCCIF, VCCLNA
3.0
3.0
VCO REGULATOR
Output Voltage, 3.0 < VBATT < 4.6 V
TEMPERATURE RANGE
1835
MHz
64
65
1.0
V p-p
24
70
450
1.76
330
dB
dB
mV p-p
V
Ω
22
0.90
2.40
70
±2
mV/dB
V
V
dB
dB
93
59
270
mA
mA
µA
4.6
3.6
V
V
2.65
2.85
V
–20
+85
°C
3.3
Specifications subject to change without notice.
–2–
REV. 0
AD6190
ABSOLUTE MAXIMUM RATINGS 1
NOTES
Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the
device at these or any other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute maximum rating
conditions for extended periods may affect device reliability.
2
Thermal Characteristics: 28-lead SSOP package θJA = 122°C/W.
1
Supply Voltage
VBATT, VCCIF, LNAVCC, VCCTX to GND . . . . +5.5 V
Maximum RF Input Level Without Damage . . . . . . . +20 dBm
Internal Power Dissipation2 . . . . . . . . . . . . . . . . . . . . 500 mW
Operating Temperature Range . . . . . . . . . . . –25°C to +85°C
Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C
Lead Temperature Range
(Soldering, 60 sec) . . . . . . . . . . . . . . . . . . . . . . . . . . +300°C
ORDERING GUIDE
Model
Package Description
Package Option
AD6190ARS
AD6190ARSRL
28-Lead Shrink Small Outline
28-Lead Shrink Small Outline, Supplied on Reels, 1500 Units per Reel
RS-28
Minimum order quantity 25,000 units.
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the AD6190 features proprietary ESD protection circuitry, permanent damage
may occur on devices subjected to high energy electrostatic discharges. Therefore,
proper ESD precautions are recommended to avoid performance degradation or loss of
functionality.
WARNING!
ESD SENSITIVE DEVICE
MODULUS CONTROL
82pF
TXON
VCOON
VBATT
(3.0-4.5VDC)
AD6190
1nF
PRESCALER
OUT
1.96kV
64/65
1
R3
51.1V
82pF
82pF
2
82pF
82pF
3
0.1mF
220V
Q1
39V
15nH
VCCTX
(3.3VDC)
10nF
82pF
REG
10nF
VCC DRIVER
(3.3VDC)
8.2nH
TRANSMIT
RF OUT
4
2.2pF
L1
5
TUNE
VOLTAGE IN
C1
15nH
10V
IN
6
82pF
39V
42
LIMITER OUT
D1 L2
15nH
7
0.1mF
82pF
8
RSSI OUT
220V
10nF
82pF
RXON
2.2pF
82pF
VCCLNA
(3.3VDC)
15nH
LNA IN
10
TRANSMIT
IF
IN
100nF
9
2.75 VDC
0.1mF
82pF
82pF
11
82pF
54.9V
301V
12
F1
6.8pF
RSSI
1kV
6.8mH
(TDK2012)
82pF 10V
VCC MIXER
100nF 39V (3.3VDC)
13
14
27pF
F1
U1
82pF
10nF
100nF
Figure 1. Test Circuit
REV. 0
–3–
82pF
10V
VCCIF
(3.3VDC)
AD6190
PIN FUNCTION DESCRIPTIONS
No.
Pin Name
Type
Function/Description
1
PREOUT
Output
2
3
4
5
6
7
8
9
10
11
12
13
14
VCOON
VBATT
VBASE
TANK–
GND
TANK+
RSSI
TXIF
VREG
RXON
LIMIN
IFAMPCOM
IFAMPOUT
Control
Power
Power
Input
Power
Input
Output
Input
Power
Control
Input
Input
Output
15
16
17
IFAMPIN
VCCIF
RXMIXOUT
Input
Power
Output
18
19
20
21
22
23
24
25
26
27
28
LNAGND
GND
RFIN
VCCLNA
GND
LIMOUT
PAGND
RFOUT
VCCTX
TXON
PREMOD
Power
Power
Input
Power
Power
Output
Power
Output
Power
Control
Input
Prescaler Output. Usually connected to input of external low frequency
CMOS synthesizer (Fujitsu MB87006A, Siemens PMB2307, or similar).
Logic “1” turns on power to VCO, and divider/prescalers.
VBATT connection for regulator. Normally connected to 3.3 V dc or battery.
Base connection to external regulator pass transistor (MMBT3906 or similar).
Connection for VCO tank circuit (LC network).
Substrate ground connection.
Connection for VCO tank circuit (LC network).
Received Signal Strength Indicator output signal.
Accepts modulated transmit signal at 10.7 MHz IF.
Regulated VCC for LO from external pass transistor.
Logic “1” turns on power to LNA and receive mixer stages.
Input to limiting amplifier.
Input signal common for limiting amplifier.
Output of first stage of IF amplifier. Normally connected through 10.7 MHz
filter to Pin 12 (LIMIN).
Input to first stage of IF amplifier.
Local VCC connection for IF amp/limiter stages.
10.7 MHz IF Output. Normally connected through 10.7 MHz filter to IF
amplifier input (Pin 15).
Local ground for LNA.
Substrate ground connection.
LNA Input. Normally driven single-ended from 50 Ω source impedance.
VCC for LNA.
Substrate ground connection.
10.7 MHz limiter output.
Local ground for PA stage emitter. Degeneration may be added.
Transmitted RF output signal at 0 dBm level.
Local VCC connection for TX stages.
Logic “1” turns on power to transmit mixer, buffers, and PA stages.
Prescaler Modulus control (HIGH = divide-by-64; LOW = divide-by-65).
PIN CONFIGURATION
PREOUT
1
28
PREMOD
VCOON
2
27
TXON
VBATT
3
26
VCCTX
VBASE
4
25
RFOUT
TANK2
5
24
PAGND
GND
6
23
LIMOUT
TANK+
7
RSSI
AD6190
TOP VIEW 22 GND
8 (Not to Scale) 21 VCCLNA
TXIF
9
20
VREG
10
19
LNAGND
RXON
11
18
LNAGND
RFIN
LIMIN
12
17
RXMIXOUT
IFAMPCOM
13
16
VCCIF
IFAMPOUT
14
15
IFAMPIN
–4–
REV. 0
2.5
1000
2.25
900
2.0
800
1.75
700
1.5
1.25
LIMITER – V-p-p
RSSI – Volts
AD6190
3.3V
+258C
915MHz
3.3V
–258C
915MHz
1.0
3.3V
+858C
915MHz
0.75
600
500
400
300
0.5
200
0.25
100
0
–115 –105 –95
–85
–75 –65 –55
PIN – dBm
–45
–35
–25
0
–25 –15
–15
Figure 2. RSSI Voltage vs. Input Power
–5
5
15
25
35
45
TEMPERATURE – 8C
55
65
75
85
Figure 5. Limiter Output Level vs. Temperature @ 3.3 V
and 915 MHz
MKR 915.0 MHz
0.0 dBm
#AT 30 dB
2.5
2.25
2.0
MARKER
915.0 MHz
0.0 dBm
RSSI – Volts
1.75
3.0V
+258C
915MHz
1.5
1.25
L.O.
3.3V
+258C
915MHz
IMAGE
1.0
3.5V
+258C
915MHz
0.75
0.5
0.25
0
–115 –105 –95
–85
–75 –65 –55
PIN – dBm
–45
–35
–25
–15
CENTER 915.0 MHz
#RES BW 10 kHz
Figure 3. RSSI Voltage vs. Input Power
SPAN 150.0 MHz
SWP 4.50 sec
VBW 10 kHz
Figure 6. Frequency Spectrum
Tek Run: 4.00GS/s ET Average
[
5.0
T
V: 72.0ns
@: –41.5ns
C1 Freq
13.899MHz
C1 +Duty
60.1%
4.0
3.0
RSSI ERROR – dB
]
2.0
1.0
0
–1.0
–2.0
–3.0
–4.0
–5.0
–115 –105 –95
–85
–75 –65 –55
PIN – dBm
–45
–35
–25
Ch1 10.0mV
–15
Figure 7. Prescaler Output
Figure 4. RSSI Error vs. Input Power
REV. 0
M 12.5ns Ch1
–5–
0V
AD6190
PRODUCT DESCRIPTION
The AD6190 is a complete RF/IF transceiver for operation in
the 902 MHz–928 MHz Industrial, Scientific and Medical
(“ISM”) frequency band. Together with a suitable spreadspectrum controller, the AD6190 can be used to design
a spread-spectrum system compliant with FCC “Part 15”
(47CFR15.247) regulations. The AD6190 is a fully compatible
companion chip to the Zilog Z87L00 “ZPhone” frequencyhopping spread-spectrum controller.
LO
RF
IN
The AD6190 includes a receive path of LNA, image-reject
mixer, IF amplifier and limiter amplifier with RSSI. The transmit path accepts a 10.7 MHz IF input signal, and uses imagereject upconversion to the 902 MHz–928 MHz band. Frequency
control is achieved using an on-chip VCO and dual-modulus
prescaler connected to an inexpensive low frequency PLL for
channel selection and frequency hopping.
Additionally, an on-chip voltage regulator stabilizes the VCO to
prevent LO pushing due to power supply variations.
APPLYING THE AD6190
Receive Signal Path
The AD6190 Low Noise Amplifier (LNA) and image-reject
mixer together provide downconverter with a total gain of 24 dB
and a typical Noise Figure (NF) of 4.2 dB.
The LNA input port exhibits an impedance of 320-j61 at
915 MHz. In order to provide an optimum match to a 50 Ω
source, the network shown in Figure 8 should be used.
908
Figure 9. Image-Reject Mixer
The RF signal, containing both the desired signal at (FLO + FIF)
and another possible signal at the image frequency of (FLO – FIF) is
applied to two mixers in parallel. These mixers are driven by
local oscillator signals in quadrature. The mixer outputs at the
two mixer IF ports contain both the desired signal and the
image signal. However, the outputs of the two mixers are in
quadrature (shifted 90 degrees relative to each other). The
outputs of the two mixers are then shifted another 90 degrees
relative to each other in a phase-shift network. The two mixer
outputs thus contain the desired signal and the image signal
exactly 180 degrees out of phase. By adding (or subtracting) the
two signals, the undesired image signals cancel, the desired
signal components add, and image-rejection occurs. Local oscillator leakage is suppressed by the use of doubly-balanced mixers.
The mixer output that drives the input side of the first
10.7 MHz filter should also be connected through a parallel
RLC network of 6.8 pF, 1 kΩ, and 7 pF to the power supply to
match the 330 Ω filter impedance.
RF IN
2.2pF
IF
OUT
The quality of the image rejection is a function of the phase and
amplitude matching of the quadrature branches of the LO and
IF phase-shift networks. In the AD6190, image-rejection is
typically 33 dB.
82pF
50V
AD6190
908
15nH
The 10.7 MHz IF signal is then filtered and amplified by a
24 dB fixed gain. The output of this stage is further filtered, and
applied to a 6-stage limiting amplifier. The limiter output signal
is typically 450 mV p-p into a 30 kΩ, 30 pF load, with a dc
offset level of approximately 1.76 V dc.
AD6190
Figure 8. LNA Input Matching Circuit
All 10.7 MHz IF filters are assumed to be standard 330 Ω impedance ceramic types. The AD6190 RX IF signal chain and TX IF
input includes internal matching resistors for this impedance.
The frequency plan of the AD6190 provides the lowest possible
RF implementation cost. A single conversion design is used with
a 10.7 MHz IF to take advantage of the very low cost filters
available. However, since the 902 MHz–928 MHz band is wider
than twice the IF, it is possible that undesired in-band signals
will be mixed down to the IF. These images could cause interference to the desired signal. It is thus necessary to provide
tunable filtering before the receive mixer, or some other approach to eliminate interference from image signals.
When used with the Zilog Z87L00 Spread-Spectrum Controller
IC, the 10.7 MHz IF signal contains the received data encoded in
FSK modulation with approximately a ±33 kHz deviation. The
Z87L00 performs the FSK demodulation in the digital domain.
The RSSI (Received Signal Strength Indicator) signal represents
the strength of the received signal, linear in dB, and scales with
supply voltage. With a 3.3 V supply (through a 10 Ω resistor on
the VCCIF pin), an RF signal level of –100 dBm at the LNA
input will produce an RSSI voltage of approximately 900 mV.
The RSSI voltage will increase with increasing RF input level,
at approximately 22 mV/dB to approximately 2.4 V at
–30 dBm input. The RSSI output voltage remains above 2.4 V
for input levels up to +15 dBm.
In the AD6190, a technique known as “image-reject” (or SSB)
mixing is used. This technique suppresses image interference by
using a pair of mixers with quadrature local oscillators. See
Figure 9.
–6–
REV. 0
AD6190
other words, the Pin 5 and Pin 7 pads are simply extended to
form L1 and L2. Equivalent Hi-Q chip inductors in the 2.2 nH
to 4.7 nH range may be substituted.
Transmit Signal Path
The AD6190 transmit chain is designed to accept an input
signal generated by the Z87L00 device. The Z87L00 provides
a digitally-generated FSK signal at 2.508 MHz, sampled at
8.192 MSPS. This sampling process produces a signal with components at 2.508 MHz, 5.684 MHz, 10.7 MHz, 16.386 MHz,
and other higher-order image products at frequencies of (N ×
8.192 MHz ± 2.508) MHz. This signal is filtered to select the
10.7 MHz image, which is used as the transmit IF signal for the
AD6190.
The single tuning varactor, D1, (e.g., Alpha Industries SMV1233-011) and a fixed capacitor C1 (or a common anode dual
diode) are located on the ends of the lines. Note that this is a
positive supply (VREG) referenced “pump-down” tank, meaning that as the TUNE voltage is increased toward VREG, the
frequency goes down. The loop filter return should also be
referenced to VREG (not ground) in order to minimize common-mode noise pickup and frequency pushing. The designer is
cautioned to develop a tank with only as much kVCO as required to allow easy coverage of the band with respect to component tolerance and production issues, in order to minimize
phase noise and frequency pulling.
An image-reject transmit up-converts the 10.7 MHz IF signal to
the 902 MHz–928 MHz RF band, with image and spurious
outputs typically 45 dB below the desired signal, and LO leakage typically –33 dBc.
The on-chip driver can provide at least 1 mW (0 dBm) into a
50 Ω load. However, when driving an external Power Amplifier
(PA) with a gain of 15 dB or more, we recommend a nominal
driver output power no higher than –3 dBm (137 mV p-p TX IF
input level) to avoid spurious PA output products in excess of
FCC allowances. The RFOUT pin is normally connected through
an 8.2 nH dc feed inductor, and ac-coupled to the power amplifier.
39V
15nH
15nH
VTUNE (FROM
LOOP FILTER)
C1
L2
TANK–
D1
LOOP FILTER
RETURN
+3.3V
39V
15nH
GND
L1
TANK+
100nF
AD6190
8.2nH
VCLO
(FROM REGULATOR
PASS TRANSISTOR)
2.2pF
TXOUT
82pF
AD6190
TO 50V LOAD
Figure 11. Typical VCO Tank Circuit
An on-chip dual-modulus (64/65) prescaler allows the frequency
control to be done with a low-cost low-frequency PLL synthesizer chip, such as the Fujitsu MB87006A, Siemens PMB2307,
or similar.
Figure 10. TXOUT Matching Circuit
The prescaler output should be connected to ground through a
2.2 kΩ pull-down resistor. The output signal (typically 1 V p-p)
is sufficient to drive most low cost PLLs, and is usually accoupled through a 1 nF capacitor to the PLL input.
Frequency Control
The AD6190 includes an on-chip voltage controlled oscillator
for LO generation. An external varactor-tuned tank circuit controls the frequency. This VCO operates at twice the required
LO frequency for several reasons.
Layout, Grounding and Decoupling
The AD6190 is a complex device with high bandwidth and high
gain on-chip. Proper layout, grounding and decoupling, techniques are essential to realizing the full performance of the system. Each of the power supply pins should be decoupled to
ground at the chip using a 82 pF chip capacitor in parallel with
a 10 nF chip capacitor. The VCCIF pin requires a 10 Ω series
resistor in addition to the 82 pF shunt capacitor.
First, it is a simple matter to generate the I and Q LO components needed for the image-reject mixers by starting with a LO
at twice the desired frequency. The divide-by-two process can
easily provide coarse quadrature signals. Any remaining phase
error is further reduced by an on-chip connection network.
Second, by keeping the oscillator operating at a frequency far
removed from the RF carrier frequency, parasitic feedback from
either the transmit signal or strong received signals is minimized.
This reduces VCO “pulling” effects.
Voltage Regulator
The AD6190 includes an on-chip voltage regulator to stabilize
the supply voltage for the local oscillator, isolating it from any
variations or noise on the main power supply voltage in the
system. This regulator is nominally set for 2.75 V output. An
external PNP pass transistor provides the needed output current
for the VCO.
A typical series resonant VCO tank circuit is shown in Figure
11. The oscillator actually operates at twice the required LO
frequency band. The tank inductors (L1, L2) may be implemented as printed traces on the PC board or as lumped circuit chip
components. The printed lines are implemented in nonmicrostrip
to produce higher Q. At least two foil layers should be removed
immediately under the tank area. A suitable tank structure can
be formed from two parallel lines, each approximately 7 mm
long by 0.3 mm wide, continuing out from the device pads. In
REV. 0
This regulator is intended to stabilize the voltage for the LO
only, and should not be used for other circuitry. VBATT may
be connected to a 3.3 V dc preregulator or to the preconditioned three-cell battery system.
–7–
AD6190
Mode Controls
OUTLINE DIMENSIONS
The AD6190 is designed as a time-division-duplex (TDD)
radio. This means that the transmitter and receiver operate at
different times. The AD6190 includes control pins to shut down
unused portions of the circuit when not needed, saving power,
as shown in the table below. For any mode except “Sleep,”
power must be applied to VBATT Pin 3 and to all VCC Pins
(16, 21 and 26) to ensure proper operation.
Dimensions shown in inches and (mm).
28-Lead Shrink Small Outline
(RS-28)
15
1
14
0.212 (5.38)
0.205 (5.21)
28
0.311 (7.9)
0.301 (7.64)
NOTE: Do not enable both the transmit and receive paths
simultaneously.
Table I.
Mode
RXON
TXON
VCOON Notes
Receive
Transmit
“Sleep”
VCO Only
1
0
0
0
0
1
0
0
1
1
0
1
0.07 (1.79)
0.066 (1.67)
0.078 (1.98) PIN 1
0.068 (1.73)
Allows VCO/PLL
to settle prior to
transmit time slot.
C3231–8–1/98
0.407 (10.34)
0.397 (10.08)
0.015 (0.38)
0.010 (0.25)
SEATING 0.009 (0.229)
PLANE
0.005 (0.127)
8°
0°
0.03 (0.762)
0.022 (0.558)
PRINTED IN U.S.A.
0.008 (0.203) 0.0256
(0.65)
0.002 (0.050) BSC
–8–
REV. 0