SIRENZA ML2726

ML2726
2.4GHz Low-IF 2.0Mbps FSK Transceiver
Preliminary Datasheet
GENERAL DESCRIPTION
FEATURES
The ML2726 is a fully integrated 2.0Mbps frequency
shift keyed (FSK) transceiver that operates in the
unlicensed 2.4GHz ISM frequency band. The device
has been optimized for digital cordless telephone
applications and includes all the frequency generation,
receive and transmit functions. Automatically adjusted
filters eliminate mechanical tuning. Closed loop
modulation eliminates frequency drift and permits
practically unlimited TX duration. The transmitter
generates a 3dBm FSK output signal.
The 2.0Mbps data rate permits data spreading, such as
Direct Sequence Spread Spectrum (DSSS) modulation,
which improves range. The dual conversion Low-IF
receiver has all of the sensitivity and selectivity
advantages of a traditional super-heterodyne without
requiring costly, bulky external filters, while providing
the integration advantages of direct conversion.
The phase locked loop (PLL) synthesizer is completely
integrated, including the voltage controlled oscillator
(VCO), tuning circuits, and VCO resonator. This allows
the ML2726 to be used in frequency hopped spread
spectrum (FHSS) applications.
The ML2726 contains internal voltage regulation. It
also contains PLL and transmitter configuration
registers. The device can be placed in a low power
standby mode for current sensitive applications. It is
packaged in a “Green” Pb-Free 32TQFP.
ƒ
Complete 2.4GHz FSK Transceiver
- High data rate (2.048 Mbps)
- -80dBm sensitivity @ 0.1% BER (typ)
- 3dBm Output Power (differential, typ)
ƒ
Closed Loop TX Modulation
ƒ
Low IF Receiver: No external IF filters required.
ƒ
Fully Integrated frequency synthesizer:
- No external resonator required.
ƒ
Sigma-Delta Fractional-N two-port modulator
ƒ
Automatic Filter Alignment
- No manufacturing adjustments required.
ƒ
No external data slicer components required
ƒ
Control outputs correctly sequence and control PA
ƒ
3-wire control interface
ƒ
Analog RSSI output
APPLICATIONS
ƒ
2.4GHz FSK Data Transceivers
- Digital Cordless Telephones
- Wireless PC Peripherals
PIN CONFIGURATION
GNDDMD
VBG
RVQMIF
RSSI
RVDMD
DIN
VDD
DOUT
29 28 27
- Wireless Game Controllers
- Wireless Streaming Media
XCEN
32 31 30
1
26 25
24
VCCA
RXON
2
23
RVLO
PAON
3
22
TXOB
BLOCK DIAGRAM
AOUT
EN
4
21
TXO
DATA
5
20
GNDRXMX2
CLK
6
19
GNDRXMX
AOUT
7
18
GNDRF
VSS
8
9
10 11
12 13 14
17
15 16
Filter
Alignment
RXI
GND
RVVCO
VTUNE
VVREG
GNDPLL
QPO
RVPLL
FREF
ML2726DH
TEMP RANGE
o
PACKAGE
Test Mux
Quadrature
Divider
Mode
Control
Two-port
Modulator
2
Control
Registers
1.6 GHz
VCO
-10 C to +60 C 32TQFP 7x7x1mm Antistatic Tray (250)
PLL
Divider
Bandgap
Ref.
Divider
P.D.
Tape & Reel (2500)
VTUNE
TPC
PAON
RXON
XCEN
Parallel
control lines
DIN
Transmit Data In
PACK (QTY)
o
ML2726DH-T -10oC to +60 oC 32TQFP 7x7x1mm
RSSI
Transmit
Mixer
TXO/TXOB
2.4 GHz
Output
DOUT
Receive Data
Out
RSSI
Divide
by 2
ORDERING INFORMATION
PART #
F
to
V
Quadrature
Downmixers
RXI
2.4 GHz
Receive Input
DATA
Serial
CLK Control Bus
EN
FREF
Frequency
Reference
QPO
PLL Loop
Filter
OCT 2007
EDS-105982 REV P01
ML2726
TABLE OF CONTENTS
GENERAL DESCRIPTION ........................................................................................................................................... 1
PIN CONFIGURATION................................................................................................................................................. 1
ORDERING INFORMATION ........................................................................................................................................ 1
FEATURES................................................................................................................................................................... 1
APPLICATIONS............................................................................................................................................................ 1
BLOCK DIAGRAM ........................................................................................................................................................ 1
TABLE OF CONTENTS................................................................................................................................................ 2
SIMPLIFIED APPLICATIONS DIAGRAM..................................................................................................................... 3
ELECTRICAL CHARACTERISTICS............................................................................................................................. 4
PIN DESCRIPTIONS.................................................................................................................................................... 7
FUNCTIONAL DESCRIPTION ................................................................................................................................... 12
MODES OF OPERATION .......................................................................................................................................... 13
DATA INTERFACE ..................................................................................................................................................... 15
CONTROL INTERFACES AND REGISTER DESCRIPTIONS .................................................................................. 17
DATA INTERFACES .................................................................................................................................................. 22
ADDITIONAL PERFORMANCE INFORMATION....................................................................................................... 24
PHYSICAL DIMENSIONS (INCHES/MILLIMETERS) ................................................................................................ 24
WARRANTY ............................................................................................................................................................... 25
PRELIMINARY DATASHEET
OCT 2007
2
EDS-105982 REV P01
ML2726
SIMPLIFIED APPLICATIONS DIAGRAM
DOUT
DOUT 32
PAON
AOUT
AOUT 7
3 PAON
RSSI
RSSI 28
ANTENNA
LNA
FREF
RXI
17 RXI
9
DATA 5
CLK 6
EN 4
ML2726
T/R
SWITCH
RXON 2
FREF
CLK,
DATA
EN
3
BASEBAND
IC
XCEN,
RXON
2
XCEN 1
TXOB
TXO
PA
22 TXOB
DIN 30
21 TXO
VTUNE
15
QPO
11
VTUNE
220Ω
VBG
26
QPO
DIN
VCCA
BATTERY
AND
PROTECTIO
NCIRCUITS
220nF
18nF
100nF
14 RVVCO
Figure 1: Typical ML2726 Application Diagram
(PLL Filter BW shown above: 22 KHz typical)
PRELIMINARY DATASHEET
OCT 2007
3
EDS-105982 REV P01
ML2726
ELECTRICAL CHARACTERISTICS
ABSOLUTE MAXIMUM RATINGS
Absolute maximum ratings are those values beyond which the device could be permanently damaged.
maximum ratings are stress ratings only and functional device operation is not implied.
Absolute
VCCA, VDD ................................................................................................................................................................. 5.5V
Junction Temperature .............................................................................................................................................. 150°C
Storage Temperature Range...................................................................................................................... -65°C to 150°C
Lead Temperature (Soldering, 10s) ......................................................................................................................... 260°C
OPERATING CONDITIONS
Normal Temperature Range......................................................................................................................... -10°C to 60°C
VCCA Range ...................................................................................................................................................2.7V to 4.5V
VDD Range .....................................................................................................................................................2.7V to 3.3V
Thermal Resistance (θJA)....................................................................................................................................... 70°C/W
Unless otherwise specified, VCCA=VDD=3.3V, TA=25°C, fREF=12.288MHz, Data Rate=2.048Mbps, 22kHz Loop Filter
as shown in Figure 1.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
2.7
3.3
4.5
V
3.3
V
POWER CONSUMPTION
VCCA
Analog supply (VCCA)
VDD
Digital Supply voltage
VDD pin (VCCA ≥ VDD always)
VBG
Bandgap Voltage
VBG pin 26, IO=0μA
ISTBY
Supply current, STANDBY mode
DC supply connected, XCEN low
10
120
μA
IRX
Supply current, RECEIVE mode
RX chain active, data being received
55
76
mA
ITX
Supply current, TRANSMIT mode
POUT=3dBm
50
76
mA
2.485
GHz
2.7
1.23
V
SYNTHESIZER
fC
Carrier frequency range
δf
Channel Spacing
3072
kHz
IP
Charge Pump sink/source current
+/-5.5
mA
ΦN
Phase noise at TXO
1.2MHz
3MHz
>7MHz
Closed loop, loop filter bandwidth
13KHz
Lock time for channel switch
From EN asserted to RX valid
data(RX), or PAON high (TX)
1 Channel
5 Channels
Full Range
110
185
250
125
220
300
μs
tFH
2.4
dBc/Hz
-95
-115
-125
μs
μs
tTX2RX
Lock time for TX/RX
RXON High to Valid RX data
70
120
μs
tRX2TX
Lock time for RX/TX
RXON Low to PAON high
63
75
μs
tWAKE
Lock up time from standby
XCEN high to Valid RX data, XCEN
240
325
μs
PRELIMINARY DATASHEET
OCT 2007
4
EDS-105982 REV P01
ML2726
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
low period >120 seconds
fFREF
Reference signal frequency
RD0=0, RD1=0
RD0=0, RD1=1
RD0=1, RD1=0
RD0=1, RD1=1
VFREF
Reference signal input level
sine wave, AC coupled
ZIN
Receiver input impedance
fc=2445MHz
NF
Receiver noise figure
fc=2445MHz
16.5
dB
Data Rate
FSK modulation, fdev=+/-768kHz
2.048
Mbps
Input Sensitivity
<12.5% CER at 2.048Mchip/s
<0.1% BER at 2.048Mbps
-89
-80
dBm
dBm
BWRX
Bandwidth
3dB Bandwidth
1155
kHz
PIMAX
Maximum RX RF input
<12.5% CER at 2.048Mchip/s
<0.1% BER at 2.048Mb/s
Receiver Input IP3
Test tones 2 and 4 channels away
9.216
12.288
18.432
24.576
2.0
MHz
MHz
MHz
MHz
VCCA
VPP
RECEIVER
DRRX
S
IIP3
Ω
+5
-4
LO leakage at RXI
IRR
Mixer Image Rejection Ratio
Adjacent channel rejection
Measured at 3.5MHz offset
dBm
dBm
-15
dBm
-60
dBm
35
dB
6
31
36
dB
dB
dB
-3
-80dBm wanted signal <10 BER
Single 2GFSK modulated interferer
with a 2.0MHz –20dBc bandwidth
1 channel away
2 channels away
3 or more channels away
IF FILTERS
fIFC
BWIF
IF filter center frequency
After Automatic Filter Alignment
1.536
MHz
IF filter 3dB bandwidth
After Automatic Filter Alignment
2108
kHz
LIMITER, AGC, AND FM DEMODULATOR
tOVLD
From +15dBm at input
Eb/No
For 0.1% BER
10.5
dB
Co-Channel rejection, 0.1% BER
-80 dBm, modulated with 2.048Mbps
GFSK, BT=0.5, PRBS data
10.5
dB
1.1
V
VODC
Quiescent voltage @ AOUT
VOPK
Output voltage swing AOUT
VOL
AOUT open-drain voltage
5
0.55
IO=100μA, TPC Mode
12
μs
Recovery from overload
1.1
VPP
0.4
V
RSSI PERFORMANCE
tRRSSI
RSSI rise time No Signal to
-15dBm into the IF mixer
20pF load, 20% to 80%
4.5
μs
tFRSSI
RSSI fall time, < -15dBm to
No Signal into the IF mixer
20pF load, 20% to 80%
3.0
μs
GRSMID
RSSI sensitivity
(V-40dBm – V-60dBm)/20dB
28
36
VRSMX
RSSI maximum voltage
See Figure 3
1.8
2.3
PRELIMINARY DATASHEET
OCT 2007
5
42
mV/dB
V
EDS-105982 REV P01
ML2726
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
VRSMD
RSSI midrange voltage
-40dBm into RXI
1.4
1.7
2.0
V
VRSMN
RSSI minimum voltage
No signal into RXI
VRSMXC
RSSI maximum voltage (clipped)
-10dBm into RXI
75
mV
1.6
1.95
V
TRANSMIT RF MIXER
POSE
Output power, single ended
TRXO or TRXOB, fC=2.445GHz
-3
1
5
dBm
PODIF
Output power, differential
P(TRXO,TRXOB), fC=2.445GHz
-1
3
6
dBm
ZOUT
Output impedance
TRXO or TRXOB, fC=2.445GHz
Ω
12+j0
TRANSMIT MODULATION
fDEV
Modulation Deviation, @2.4GHz
200us of consecutive ‘1’s or ‘0’s
750
fOS
Modulation center frequency offset
50us after RXON low
-75
768
786
kHz
+75
kHz
TRANSMIT DATA FILTER
BWTX
Transmit Data Filter Bandwidth
3dB Bandwidth
TX spurious
Image
2.1
MHz
-25
-20
dBc
dBc
INTERFACE LOGIC LEVELS
INPUTS (DIN, XCEN, RXON, DATA, CLK, EN)
VIH
Input high voltage
VIL
(never exceed VDD)
0.75*VDD
VDD
V
Input low voltage
0
0.25*VDD
V
IB
Input bias current
-5
5
μA
CIN
Input capacitance
(measured at 1MHz)
0
4
pF
OUTPUTS (DOUT, PAON)
VOH
DOUT high voltage
Io=0.1mA
VOL
DOUT low voltage
Io=-0.1mA
Io
DOUT sink/source current
VOH
PAON output high voltage
Sourcing 0.5mA
VOL
PAON output low voltage
Sinking 0.5mA
Io
PAON source/sink current
VDD-0.4
V
0.4
V
0.1
mA
VDD-0.4
V
0.4
0.5
V
mA
3 WIRE SERIAL BUS TIMING
tr
CLK input rise time
tf
CLK input fall time
tck
CLK period
50
ns
tew
CLK pulse width
100
ns
tl
Delay from last CLK falling edge
15
ns
tse
EN setup time to ignore next
rising CLK
15
ns
ts
DATA-to-CLK setup time
15
ns
th
DATA-to-CLK hold time
15
ns
PRELIMINARY DATASHEET
See Figure 4
OCT 2007
6
15
ns
15
ns
EDS-105982 REV P01
ML2726
PIN DESCRIPTIONS
PIN
SIGNAL
NAME
I/O
FUNCTION
DIAGRAM
POWER & GROUND
8
VSS
GND
Digital Ground. Ground for digital I/O
circuits and control logic.
N/A
10
RVPLL
PWR
PLL Supply. DC power supply
decoupling point for the PLL dividers,
phase detector, and charge pump. This
pin is connected to the output of the
regulator and to the PLL supplies. There
must be a 220nF capacitor to ground
from this pin to decouple (bypass) noise
and to stabilize the regulator.
See Pin 11 below.
12
GNDPLL
GND
Ground for the PLL dividers, phase
detector, and charge pump.
N/A
13
VVREG
PWR
DC Power Supply Input to the VCO
voltage regulator. Must be connected to
RVQMIF (pin 27) or RVDMD (pin 29) via
decoupling network.
N/A
14
RVVCO
PWR
DC power supply decoupling point for the
VCO. Connected to the output of the
VCO regulator. A 220nF capacitor must
be tied between this pin and ground to
decouple (bypass) noise and to stabilize
the regulator.
N/A
16
GND
GND
DC ground for VCO and LO circuits.
N/A
18
GNDRF
GND
Ground return for the Receive RF input
and Transmit RF output.
VCCA
24
0.7V
RXI
4k
17
VSS (PIN 8)
VCCA
(PIN 24)
GNDRF 18
8
VSS
19
GNDRXMX
GND
Signal ground for the Receive mixers.
N/A
20
GNDRXMX2
GND
Signal ground for the Receive mixers.
N/A
PRELIMINARY DATASHEET
OCT 2007
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EDS-105982 REV P01
ML2726
PIN
SIGNAL
NAME
I/O
FUNCTION
DIAGRAM
23
RVLO
PWR
DC power supply decoupling point for the
LO Chain. Connected to the output of a
regulator. A 220nF capacitor must be tied
between this pin and ground to decouple
(bypass) noise and to stabilize the
regulator.
N/A
24
VCCA
PWR
DC power supply Input to Voltage
Regulators and unregulated loads: 2.7 to
3.8V. VCCA is the main (or master)
analog VCC pin. There must be
capacitors to ground from this pin to
decouple (bypass) supply noise.
N/A
25
GNDDMD
GND
DC ground to IF, Demodulator, and Data
Slicer circuits.
N/A
27
RVQMIF
PWR
DC power supply decoupling point for
Quadrature Mixer and IF filter circuits. A
220nF capacitor must be tied between
this pin and ground to decouple (bypass)
noise and to stabilize the regulator.
N/A
29
RVDMD
PWR
DC power supply decoupling point for IF,
Demodulator, and Data Slicer circuits. A
220nF capacitor must be tied between
this pin and ground to decouple (bypass)
noise and to stabilize the regulator.
N/A
31
VDD
PWR
DC power supply input to the interface
logic and control registers. This supply is
not connected internally to any other
supply pin, but its voltage must be less
than or equal to the VCCA supply and
greater than 2.7V. A capacitor must be
tied between this pin and ground to
decouple (bypass) noise.
N/A
I (Analog)
Receive RF Input. Nominal impedance at
2445MHz is 2.6-j2.6 with a simple
matching network required for optimum
noise figure. This input connects to the
base of an NPN transistor and should be
AC coupled.
TRANSMIT/RECEIVE
17
RXI
VCCA
24
0.7V
RXI
4k
17
VSS (PIN 8)
VCCA
(PIN 24)
GNDRF 18
8
VSS
PRELIMINARY DATASHEET
OCT 2007
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EDS-105982 REV P01
ML2726
21
TXO
O (Analog)
TX RF open-collector output. This output
requires a DC path to VCCA.
22
TXOB
O (Analog)
Complementary TX RF open-collector
output. This output requires a DC path to
VCCA. For single-ended output
applications, this pin should be
connected to a dummy load that includes
a DC path to VCCA.
TXO
TXOB
21
22
18
GNDRF
DATA
7
AOUT
A (Analog)
Multi-function Output. In Analog output
mode this is output drives an off chip
data slicer. In Transmit power control
mode this is an open drain output, which
is pulled low when the TPC bit is serial
register #1, is clear. Transitions on TPC
are synchronized to the falling edge of
RXON. In analog test modes this pin and
the RSSI output become test access
points controlled by the serial control
bus.
TPQ
MUX
VDD
31
TPC
TPC
MUX
7
AOUT
100Ω
8
8
VSS
VSS
AOUT
MUX
30
DIN
I (CMOS)
Transmit Data Input. Drives the transmit
pulse shaping circuits. Serial digital data
on this pin becomes FSK modulation on
the Transmit RF output. The logic timing
on this pin controls data timing. Internal
circuits determine the modulation
deviation. This is a standard CMOS input
referenced to VDD and VSS.
32
DOUT
O (CMOS)
Serial digital output after demodulation,
chip rate filtering and center data slicing.
A CMOS level output (VSS to VDD) with
controlled slew rates. A low drive output
designed to drive a PCB trace and a
CMOS logic input while generating
minimal RFI. In digital test modes this pin
becomes a test access port controlled by
the serial control bus.
See Pin 1 below.
VDD
31
250Ω
32 DOUT
8
PRELIMINARY DATASHEET
OCT 2007
9
VSS
EDS-105982 REV P01
ML2726
MODE CONTROL AND INTERFACE LINES
1
2
XCEN
RXON
I (CMOS)
I (CMOS)
VDD
Enables the bandgap reference and
voltage regulators when high. Consumes
only leakage current in STANDBY mode
when low. This is a CMOS input, and the
thresholds are referenced to VDD and
VSS.
TX/RX Control Input. Switches the
transceiver between TRANSMIT and
RECEIVE modes. Circuits are powered
up and signal paths reconfigured
according to the operating mode. This is
a CMOS input, and the thresholds are
referenced to VDD and VSS.
31
XCEN
1
RXON
2
DIN
30
8
VSS
3
PAON
O (CMOS)
PA Control Output. Enables the off-chip
PA at the correct times in a Transmit slot.
Goes high when transmit RF is present
at TXO; goes low 5μs before transmit RF
is removed from TXO. Has interlock logic
to shut down the PA if the PLL does not
lock.
VDD
31
3
8
9
FREF
I
Input for the 9.216MHz, 12.288MHz,
18.432MHz or 25.576MHz reference
frequency. This input is used as the
reference frequency for the PLL and as a
calibration frequency for the on-chip
filters. An AC-coupled sine or square
wave source drives this self-biased input.
PAON
VSS
VCCA
24
9
40k
FREF
40k
8
VSS
11
QPO
O
Charge Pump Output of the phase
detector. This is connected to the
external PLL loop filter.
RVPLL
10
11 QPO
8
VSS
PRELIMINARY DATASHEET
OCT 2007
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EDS-105982 REV P01
ML2726
15
VTUNE
I
VCCA
VCO Tuning Voltage input from the PLL
loop filter. This pin is very sensitive to
noise coupling and leakage currents.
24
1.25V
VTUNE
15
3.7k
8
VSS
26
VBG
O
Bandgap Decouple Voltage. Decoupled
to ground with a 220nF capacitor.
28
RSSI
O
Buffered Analog RSSI output with a
nominal sensitivity of 35mV/dB. In analog
test modes, this pin and the AOUT output
become test access points controlled by
the serial control bus.
N/A
TPI
MUX
VCCA
24
RSSI
OP
AMP
RSSI
MUX
28 RSSI
100 Ω
8
VSS
SERIAL BUS SIGNALS
4
5
6
EN
DATA
CLK
I (CMOS)
I (CMOS)
I (CMOS)
PRELIMINARY DATASHEET
Control Bus Enable. Enable pin for the
three-wire serial control bus that sets the
operating frequency and programmable
options. The control registers are loaded
on a low-to-high transition of the signal.
Serial control bus data is ignored when
this signal is high. This is a CMOS input,
and the thresholds are referenced to
VDD and VSS.
Serial Control Bus Data. 16-bit words,
which include programming data and the
two-bit address of a control, register. This
is a CMOS input, and the thresholds are
referenced to VDD and VSS.
VDD
31
EN
4
5.5k
DATA 5
CLK
1.7p
6
8
VSS
Serial control bus data is clocked in on
the rising edge when EN is low. This is a
CMOS input; the thresholds are
referenced to VDD and VSS.
OCT 2007
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EDS-105982 REV P01
ML2726
FUNCTIONAL DESCRIPTION
The ML2726 is a fully integrated 2.0Mbps frequency shift keyed (FSK) transceiver that operates in the unlicensed
2.4GHz ISM frequency band. The device has been optimized for digital cordless telephone applications and includes all
the frequency generation, receive and transmit functions for a raw data rate of 2.0Mbps. This high data rate allows for
data spreading, such as Direct Sequence Spread Spectrum (DSSS) modulation, which improves range. The ML2726
receiver architecture is a dual conversion Low IF, which has all of the sensitivity and selectivity advantages of a
traditional super-heterodyne receiver without requiring costly, bulky external filters.
The RF mixer down-converts the 2.4GHz RF input signal to the first intermediate frequency (IF), where it is filtered to
remove adjacent channel signals. An active image reject mixer converts this signal down to a Low IF frequency, where
the data is limited, filtered, and demodulated. This architecture provides all the benefits of direct conversion to
baseband while maintaining the stability and robustness of a traditional super-heterodyne.
A single synthesizer is used for both the receiver and the FSK transmitter. The phase locked loop (PLL) is completely
integrated, including the voltage controlled oscillator (VCO), tuning circuits, and VCO resonator.
In RECEIVE MODE, the ML2726 is a dual conversion Low IF receiver. No external SAW filters are required. The
integrated image reject mixer gives sufficient rejection in this channel. All channel filtering and demodulation is
performed using active filters, which are automatically aligned. A matched bit rate filter and a data slicer follow the
demodulator. The sliced data is provided at the DOUT pin, and the analog data is available at AOUT.
In TRANSMIT MODE, the ML2726 generates a 2.4GHz output using the transmit mixer. An auto-aligned transmit data
filter and modulation compensation circuit results in an adjustment-free transmitter. The VCO is modulated by the
transmit data, which is put through a sigma-delta fractional-N PLL ensuring modulation accuracy. This modulation
occurs while the phase locked loop is closed, thus allowing practically infinite transmit or receive times with excellent
frequency accuracy and stability. A 3dBm FSK-modulated differential signal is output at the TXO/TXOB pins at the
2.4GHz carrier frequency.
The integrated PLL frequency synthesizer includes a fully integrated VCO, prescaler, phase detector and charge pump.
The reference frequency is generated from the incoming signal at the FREF pin, which can be 9.216MHz, 12.288MHz,
18.432MHz, or 24.576MHz. The loop filter is external to allow customers to optimize their loop bandwidth to their
system’s lock time and in-band phase noise requirements. This frequency-agile synthesizer allows the ML2726 to be
used in frequency hopped spread spectrum (FHSS) applications with nominal channel spacing of 3.072MHz. Carrier
frequency is programmed via the configuration registers and 3-wire serial interface. The VCO tank circuit (inductor and
varactor) is fully integrated.
AOUT
F
to
V
Quadrature
Downmixers
RXI
2.4 GHz
Receive Input
Filter
Alignment
RSSI
RSSI
Test Mux
Divide
by 2
Quadrature
Divider
Mode
Control
Transmit
Mixer
TXO/TXOB
2.4 GHz
Output
DOUT
Receive Data
Out
Two-port
Modulator
2
Control
Registers
PLL
Divider
Ref.
Divider
P.D.
VTUNE
Parallel
control lines
DIN
Transmit Data In
1.6 GHz
VCO
Bandgap
TPC
PAON
RXON
XCEN
DATA
Serial
CLK Control Bus
EN
FREF
Frequency
Reference
QPO
PLL Loop
Filter
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Figure 2: ML2726 Internal Block Diagram
MODES OF OPERATION
There are three key modes of operation:
ƒ
STANDBY:
All circuits powered down, except the control interface (Static CMOS)
ƒ
RECEIVE:
Receiver circuits active
ƒ
TRANSMIT:
Modulated RF output from IC
The two operational modes are RECEIVE and TRANSMIT, controlled by RXON. XCEN is the chip enable/disable
control pin, which sets the part in operational or STANDBY modes. The relationship between the parallel control lines
and the mode of operation of the IC is given in Table 1.
XCEN
RXON
MODE
FUNCTION
0
X
STANDBY
Control interfaces active, all other circuits powered down
1
1
RECEIVE
Receiver time slot
1
0
TRANSMIT
Transmit time slot
Table 1: Modes of Operation
MODE CONTROL
The ML2726 is intended for use in TDD and TDMA radios in battery-powered equipment. To minimize power
consumption it is designed to switch rapidly from a low power mode (STANDBY) to an active mode. The ML2726 can
also make a quick transition from receive to transmit for TDD operation. Prior to transmitting or receiving, time should
be allowed for the PLL to lock and for the filters to align. When the ML2726 is operated in single-carrier TDD mode, the
LO is automatically shifted by the second (low) IF frequency when the device is switched between RECEIVE and
TRANSMIT modes.
ML2726 carrier frequency can be changed (hopped) at any time, but is usually changed between transmissions. Carrier
frequency (channel) is modified in the ML2726 by writing a corresponding new value to the PLL frequency register
(Register 1)
RECEIVE
The ML2726 uses a double-conversion super-heterodyne receiver with a nominal second IF of 1.536MHz. The signal
flow in RECEIVE mode is from the RF input, through an RF down-conversion mixer and integrated IF filter, image reject
quadrature mixer, integrated Low IF filter, hard limiter, frequency to voltage converter, and data filter to the AOUT pin
and data slicer where the digital NRZ data is available at the DOUT pin. A 20dB step AGC extends the dynamic range
of the receiver. The ML2726 receive chain is a Low IF receiver using advanced integrated radio techniques to eliminate
external IF filters and minimize external RF filter requirements. The precision filtering and demodulation circuits give
improved performance over conventional radio designs using external filters while providing integration comparable to
advanced direct conversion radio designs.
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ML2726
Receive Signal Strength Indication (RSSI)
RSSI is an indication of field strength. It can be used to control transmit power to conserve battery life or it may be used
to determine if a given channel is occupied. See Figure 3.
Figure 3: RSSI Voltage vs. Input Signal Level
Automatic Filter Alignment
When the ML2726 is placed in RECEIVE mode, it automatically tunes all the internal filters using the reference
frequency from the FREF pin. When the chip is powered up (VDD first applied), the tuning information is reset to midrange. This self-calibration sets:
ƒ
Discriminator center frequency
ƒ
IF filter center frequency and bandwidth
ƒ
Receiver data low-pass filter bandwidth
ƒ
Transmit data low-pass filter bandwidth
TRANSMIT MODE
In TRANSMIT mode, the PLL is closed to eliminate frequency drift. A two-port modulator modulates both the VCO and
the fractional-N PLL. The VCO is directly modulated with filtered FSK transmit data. The PLL is driven by a sigma-delta
modulator, which ensures that the PLL follows the mean frequency of the modulated VCO.
The transmit modulation filter is automatically tuned during every RECEIVE time, alleviating the need for production
alignment. Asserting RXON enables the ML2726. The rising edge of XCEN triggers a complete calibration of all the onchip filters, which takes up to 256μs, which ensures the modulation filters are aligned to prevent unwanted spurious
emissions.
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ML2726
PLL PROGRAMMING & CHANNEL SELECTION
The ML2726 PLL is programmed via control register 2 to the set RF center frequency of operation of the radio. The PLL
does not need to be (though it can be) reprogrammed between RECEIVE and TRANSMIT modes. Nominal channel
separation is 3.076MHz, allowing for over 40 non-overlapping channels in any given location. With careful planning,
channels can be programmed in 1536kHz steps as long as care is exercised to insure that two radio links will not share
spectrum at any one time. The equation to determine channel center frequency from the ML2726 control register word
is:
fC = CHQ<0:11>*1.536MHz
STANDBY MODE
In STANDBY mode, the ML2726 transceiver is powered down. The only circuits active are the control interfaces, which
are digital CMOS to minimize power consumption. The serial control interface and control registers remain powered up
and will accept and retain programming data as long as the digital supply is present. When exiting STANDBY mode, the
device must be kept in RECEIVE mode for 256μs to allow for filter self-calibration.
TEST MODE
The RF to digital functionality of the ML2726 requires special test mode circuitry for IC production test and radio
debugging. A test register, accessible via the 3-wire serial interface, controls the test multiplexers. (See Table ).
DATA INTERFACE
There are two control interfaces: CONTROL and SERIAL.
CONTROL INTERFACE
The control interface provides immediate control and monitoring of the ML2726. Input signals include:
ƒ
XCEN:
Transceiver enable. Places the ML2726 in Standby or Active (when asserted) modes.
ƒ
RXON:
Receive On. Places an Active ML2726 in Receive mode when asserted.
ƒ
FREF:
Reference frequency input
Output signals include:
ƒ
RSSI:
Received Signal Strength Indicator: indicates the power of the received signal
ƒ
PAON:
External Power Amplifier Control Pin
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ML2726
SERIAL INTERFACE
A 3-wire serial interface (EN, DATA, CLK) is used for programming the ML2726 configuration registers, which control
device mode, pin functions, PLL and reference dividers, internal test modes, and filter alignment. Data words are
entered beginning with the MSB (“big-endian”). The word is divided into a leading 14-bit data field followed by a 2-bit
address field. When the address field has been decoded the destination register is loaded on the rising edge of EN.
Providing less than 16 bits of data will result in unpredictable behavior when EN goes high.
Data and clock signals are ignored when EN is high. When EN is low, data on the DATA pin is clocked into a shift
register on the rising edge of the CLK pin. This information is loaded into the target control register when EN goes high.
This serial interface bus is similar to that commonly found on PLL devices. It can be efficiently programmed by either
byte or 16-bit word oriented serial bus hardware. The data latches are implemented in CMOS and use minimal power
when the bus is inactive. Refer to Figure 4 and Table 2: 3-Wire Bus Timing Characteristics for timing and register
programming illustrations.
SYMBOL
PARAMETER
MIN
TYP
MAX
UNIT
BUS CLOCK (CLK)
tr
CLK input rise time
15
ns
tf
CLK input fall time
15
ns
tck
CLK period
50
ns
ENABLE (EN)
tew
Minimum pulse width
100
ns
tl
Delay from last CLK rising edge
15
ns
tse
Set up time to ignore next rising CLK
15
ns
BUS DATA (DATA)
ts
data to clock set up time
15
Ns
th
data to clock hold time
15
Ns
Table 2: 3-Wire Bus Timing Characteristics
tF
tS
tR
tL
t CK
tH
CLK
DATA
LSB
MSB
tEW
ADDRESS
DATA
EN
Figure 4: Serial Bus Timing for Address and Data Programming
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ML2726
CONTROL INTERFACES AND REGISTER DESCRIPTIONS
REGISTER INFORMATION
A 3-wire serial data input bus sets the ML2726’s transceiver parameters and programs the PLL circuits. Entering 16-bit
words into the ML2726 serial interface performs programming. Three 16-bit registers are partitioned such that 14 bits
are dedicated for data to program the operation and two bits identify the register address. The contents of these
registers cannot be read back via this bus.
The three registers are:
ƒ
Register 0:
PLL Configuration
ƒ
Register 1:
Channel Frequency Data
ƒ
Register 2:
Internal Test Access
Figure 5 shows a register map. Table 3 through Table 5 provide detailed diagrams of the register organization: Table 3
and Table 4 outline the PLL configuration and channel frequency registers, and Table 5 displays the filter tuning and
test mode register.
MSB
DB13
DB12
Res.
B15
DB11
Res.
B14
DB9
DB10
Res.
B13
Res.
B12
DB8
RCLP
B11
DB7
LVLO
B10
DB6
Res.
B9
DB5
TXM
TPC
B8
DB4
DB3
TXCW
B7
B6
RD1
DB2
DB1
AOUT
B5
B4
DB0
RD0
ADR1
QPP
B3
ADR0
0
B2
0
B1
B0
MSB
DB13
Res.
DB12
Res.
B15
DB9
DB11
DB10
DB8
CHQ11 CHQ10
CHQ9
CHQ8
B14
B13
B12
B11
DB7
DB6
DB5
DB4
DB3
DB2
DB1
DB0
ADR1
CHQ7
CHQ6
CHQ5
CHQ4
CHQ3
CHQ2
CHQ1
CHQ0
0
B10
B9
B8
B7
B6
B5
B3
B4
B2
ADR0
1
B1
B0
MSB
DB13
DB12
Res.
B15
DB11
Res.
B14
DB10
Res.
B13
DB8
DB9
Res.
B12
Res.
B11
DB7
Res.
B10
DB6
Res.
B9
DB5
Res.
B8
DB4
DTM2
B7
DB3
DTM1
DB2
DTM0
B6
B5
DB1
ATM2
B4
DB0
ATM1
B3
ADR1
ATM0
B2
ADR0
1
0
B1
B0
Figure 5: Configuration Register Map
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ML2726
NAME
DESCRIPTION
DEFINITION
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
RCLP
RSSI Clip Disable
LVLO
Low Voltage Lockout
Reserved
Reserved
TXM
TX RF Output Mode
TPC
Transmit Power Control
TXCW
Transmit Test Mode
RD1
Reserved
AOUT
Analog Output
RD0
Reference Frequency Select
QPP
PLL Charge Pump Polarity
ADR1
MSB Address Bit
ADR1=0
ADR0
LSB Address Bit
ADR0=0
Set all bits to 0 (zero)
0: RSSI clipped to 1.9V at –15dBm
1: RSSI not clipped
0: PAON Undisturbed
1: PAON De-asserted for VCCA<2.65V. Reset on RXON high
Set to 0
0: TX RF Output always on in TX mode
1: TX RF Output follows PAON signal
0: AOUT pin pulled to ground
1: AOUT pin high impedance
0: FSK modulation in Transmit mode
1: CW (no modulation in Transmit mode)
(See Table 7)
0: AOUT pin is Transmit Power Control
1: AOUT pin is Analog Data Out
(See Table 7)
0: For fc < fref, charge pump sources current
1: For fc < fref, charge pump sinks current
Table 3: Register 0 -- PLL Configuration Register
NAME
DESCRIPTION
DEFINITION
Reserved
Set all bits to 0 (zero)
Reserved
CHQ11
CHQ10
CHQ9
CHQ8
CHQ7
CHQ6
Channel Frequency select bits
Divide ratio=fc/1.536
CHQ5
CHQ4
CHQ3
CHQ2
CHQ1
CHQ0
ADR1
MSB Address Bit
ADR1=0
ADR0
LSB Address Bit
ADR0=1
Table 4: Register 1 – Channel Frequency Register
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NAME
DESCRIPTION
DEFINITION
Reserved
Set all bits to 0 (zero)
Digital Test Control Bits
See Table
Analog Test Control Bits
See Table
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
DTM2
DTM1
DTM0
ATM2
ATM 1
ATM 0
ADR1
MSB Address Bit
ADR1=0
ADR0
LSB Address Bit
ADR0=1
Table 5: Register 2 – Test Mode Register
Power-On State
On Power up, all register bits are cleared to the default value of 0 (zero). Power up is defined as occurring when
VDD>2.0V. The register default values are valid upon power up.
CONTROL REGISTER BIT DESCRIPTIONS
ADR<1:0>, All Registers, Bits 0-1
Address Bits: The ADR<1:0> bits are the least-significant bits of each register. Each register is divided into a data
field and an address field. The data field is the leading field, while the last two bits clocked into the register are always
the address field. When EN goes high, the address field is decoded and the addressed destination register is loaded.
The last 16 bits clocked into the serial bus are loaded into the register. Clocking in less than 16 bits results in a
potentially incorrect entry into the register.
RES (Reserved), All Registers
Reserved Bits: These bits are reserved. These bits must be cleared to 0s (zeros) for normal operation. When power is
reset, all of the registers’ data fields are cleared to 0s (zeros).
QPP - Register 0, Bit 2
Charge Pump Polarity: This bit sets the charge pump polarity to sink or source current. For a majority of applications,
this bit is cleared (QPP=0). For applications where an external inverting amplifier is used in the loop filter, this bit is set
to change the charge pump polarity (see Table 6).
QPP
PLL CHARGE PUMP POLARITY
0
fc > fref ͯ Charge pump sinks current.
1
fc > fref ͯ Charge pump sources current.
Table 6: PLL Charge Pump Polarity
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ML2726
RD0 - Register 0, Bit 3 RD1 - Register 0, Bit 5
Reference Divide: These 2 bits set the reference divider from the FREF pin to the reference input of the PLL
phase/frequency detector (see Table 7).
RD0
RD1
REFERENCE
FREF XTAL
PLL REF
DIVISION
FREQ
FREQ
CHANNEL
SPACING
0
0
9
9.216MHz
1.024MHz
1.536MHz
0
1
12
12.288MHz
1.024MHz
1.536MHz
1
0
18
18.432MHz
1.024MHz
1.536MHz
1
1
24
24.576MHz
1.024MHz
1.536MHz
Table 7: Reference Frequency Select
AOUT - Register 0, Bit 4
Analog Output Mode: This bit changes the function of the AOUT pin between an analog data output to transmit power
control (see Table 8).
AOUT
AOUT PIN FUNCTION
0
Transmit Power Control
1
Data Filter Analog Output
Table 8: AOUT Function Select
TXCW - Register 0, Bit 6
Transmit Continuous Wave: This bit produces a continuous wave (CW) transmitter output for product test when
RXON is low (see Table 99).
TXCW
TRANSMIT MODULATION
0
FSK Modulation
1
CW – No Modulation
Table 9: Transmit Modulation Mode
TPC - Register 0, Bit 7
Transmit Power Control: When the AOUT bit is low, this bit controls the state of the open-drain output pin. Although
this bit can be changed at any time, the AOUT pin only changes state at the falling edge of RXON (see Table 10).
TPC
TPC PIN STATE
0
High Impedance
1
Pulled to Ground
Table 10: TPC Pin State
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ML2726
TXM - Register 0, Bit 8
Transmit Mode: This bit controls the TX RF buffer state timing mode. It must be reset to 0 for normal operation (see
Table 1).
TXM
TXRF BUFFER BEHAVIOR
0
RF Output Always On in TX Mode
1
RF Output Follows PAON
Table 11: TXM Mode
LVLO - Register 0, Bit 10
Low Voltage Lock Out: The LVLO bit enables a transmit low voltage lockout latch, which shuts off the transmitter by
de-asserting the PAON output. This latch is set if the supply voltage drops below 2.65V and is reset when the RXON
control input goes high (see Table 2).
LVLO
PAON BEHAVIOR
0
PAON Undisturbed
1
PAON de-asserted when VCCA<2.65V,
Reset by RXON high.
Table 12: LVLO Operation
RCLP - Register 0, Bit 11
RSSI Clip Enable: The RCLP bit disables the RSSI clipping circuitry. With RCLP low, the RSSI output voltage is
clipped to a maximum of about 2.0V at –10dBm. With RCLP high, the RSSI is not clipped. (see Table 3).
RCLP
RSSI BEHAVIOR
0
RSSI output clipped to a maximum of ~1.9V at –15dBm
1
RSSI output not clipped
Table 13: RCLP Operation
CHQ <11:0> - Register 1, Bits 2-13
Channel Frequency Selection: These bits set the RF carrier frequency for the transceiver (see Table 4). The channel
frequency value is calculated by multiplying the CHQ value by 1.536. The recommended operating range value of the
CHQ is from 1,589 to 1,616. These bits must be programmed to a valid channel frequency before XCEN is asserted.
B15
B14
B13 TO B2
B1
B0
0
0
CHQ - PLL Divide Ratio
0
1
Table 14: Main Divider
The divide ratio is calculated as fC /1.536 where fC is the channel frequency in MHz.
fC=1.536 * CHQ
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ML2726
ATM<2:0> - Register 2, Bits 2-4
Analog Test Mode: The test mode selected is described in Table 5. The performance of the ML2726 is not specified in
these test modes. Although primarily intended for IC test and debug, they also can help in debugging the radio system.
The default (power-up) state of these bits is ATM<2:0>=<0,0,0>. When a non-zero value is written to the field, the RSSI
and AOUT pins become analog test access ports, giving access to the outputs of key signal processing stages in the
transceiver. During normal operation, ATM<2:0> must be set to all zeros.
ATM2
ATM1
ATM0
RSSI
AOUT
0
0
0
RSSI
Set by AOUT bit
0
0
1
No Connect
No Connect
0
1
0
I IF Filter Output
Q IF Filter Output
0
1
1
Q IF Filter – ve Output
Q IF Filter + ve Output
1
0
0
I IF Filter – ve Output
I IF Filter + ve Output
1
0
1
Data Filter + ve Output
Data Filter – ve Output
1
1
0
I IF Limiter Outputs
Q IF Limiter Outputs
1
1
1
1.67V Voltage Reference
VCO Modulation Port Input
Table 15: Analog Test Control Bits
DTM <2:0> - Register 2, Bits 5-7
Digital Test Mode: The DTM<2:0> bit functions are described in Table 6. The performance of the ML2726 is not
specified in these test modes. Although primarily intended for IC test and debug, they also can help in debugging the
radio system. The default (power up) state of these bits is DTM<2:0>=<0,0,0>. When a non-zero value is written to
these fields, the DOUT and PAON pins become a digital test access port for key digital signals in the transceiver.
During normal operation, DTM<2:0> must be set to all zeros.
DTM2
DTM1
DTM0
PAON
DOUT
0
0
0
PA Control
Data Out
0
0
1
PA Control
AGC Switch State
0
1
0
PA Control
PLL Main Divider Output
0
1
1
PA Control
PLL Reference Divider Output
1
0
0
S – D Modulation LSB
Sigma – Delta Modulation MSB
Table 16: Digital Test Control Bits
DATA INTERFACES
BASEBAND INTERFACE: DIN & DOUT
The DIN and DOUT pins are digital CMOS signals that correspond to FSK modulation of the carrier frequency. The
ML2726 is designed to operate as an FSK transceiver in the 2.4GHz ISM band. The frequency deviation and transmit
filtering is determined in the transceiver.
Data on the DIN pin is filtered and presented to the transmit two-port modulator. There is no re-timing of the bits, so the
transmitted FSK data takes its timing from the input data. In the receive chain, FSK demodulation, data filtering, and
data slicing take place in the ML2726, and the digital data is output on the DOUT pin. Bit and word rate timing recovery
are performed off chip. The data filter output is available on the AOUT pin for use with an optional external data slicer.
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RSSI & FREF
FREF (pin 9) is the master reference frequency for the transceiver. It supplies the frequency reference for the RF
channel frequency and the filter tuning. The FREF pin is a CMOS input with internal biasing resistors. It can be AC
coupled to sine or square wave source. The FREF input can also be driven by a CMOS logic output. The frequency of
the FREF input is limited to one of: 9.216MHz, 12,288MHz, 18,432MHz, or 24.576MHz.
The Received Signal Strength Indicator (RSSI) pin supplies a voltage proportional to the logarithm of the received
power level. It is normally connected to the input of a low speed ADC and is used during channel scanning to detect
clear channels on which the radio may transmit. It can also be used to set transmit power to optimize power
consumption while maintaining an acceptable bit error rate (BER).
PA CONTROL OUTPUTS (PAON & AOUT)
The PAON (PA control) is a CMOS output that controls an optional off-chip RF PA. It outputs a logic high when the PA
should be enabled and a logic low at all other times. This output is inhibited when the PLL fails to lock.
AOUT (pin 7) normally supplies the analog (not data-sliced) data output, but it can also be configured as an open-drain
output for transmit power control. This mode is controlled by the TPC bit in Register 0. This bit can be changed at any
time, but the AOUT pin will not change mode until the beginning of the next transmit slot, triggered by a falling edge on
RXON (see Figure 6 and Table 17 for details).
In analog test modes the RSSI and AOUT pins become analog test access ports that allow the user to observe internal
signals in the ML2726.
RXON
SYMBOL
PAON
t4
Output from
TRFO
t1
t2
PARAMETER
TIME/μS
T1
RXON falling edge to PAON rising edge
62.5
T2
RXON rising edge to PLL frequency
shift
6.5
T3
RXON rising edge to RECEIVE mode
70
T4
RXON rising edge to PAON falling edge
< 0.1
t3
Figure 6: Power Amplifier Interface
Table 17: Power Amplifier Timing
RF INTERFACE: RXI & TXO/TXOB
The RXI receive input (pin 17) and the TXO/TXOB differential transmit outputs (pins 21 and 22) are the only RF I/O
pins. The RXI pin requires a simple impedance matching network for optimum input noise figure. The TXO/TXOB pins
require a matching network for maximum power output into the RF power amp. If a single ended output is preferred, the
signal from the TXO pin can be matched to the power amp and the TXOB output can be shunted to a power supply
through a dummy load. The RF input and output ground (pin 18) must have a direct connection to the RF ground plane,
and the RF power supply pins must be decoupled to the same ground plane as close to the device as possible.
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ADDITIONAL PERFORMANCE INFORMATION
1.800
1.600
1.400
1.200
1.000
0.800
0.600
0.400
0.200
0.000
1570 1577 1584 1591 1597 1604 1611 1618 1625 1632 1638 1645 1652 1659 1666 1673 1679 1686 1693 1700
Figure 7: Typical VCO Tuning Voltage vs. Frequency
PHYSICAL DIMENSIONS (INCHES/MILLIMETERS)
0.354 BSC
(9.00 BSC)
0.276 BSC
(7.00 BSC)
0º - 8º
0.003 - 0.008
(0.09 - 0.20)
25
1
PIN 1 ID
0.276 BSC
(7.00 BSC)
0.354 BSC
(9.00 BSC)
0.018 - 0.030
(0.45 - 0.75)
17
9
0.032 BSC
(0.8 BSC)
0.048 MAX
(1.20 MAX)
0.012 - 0.018
(0.29 - 0.45)
SEATING PLANE
0.037 - 0.041
(0.95 - 1.05)
Note: This package meets “Green” Pb-Free requirements and is compliant with the European Union directives WEEE
(Waste Electrical and Electronic Equipment) and RoHS (Restriction of the use of certain Hazardous Substances in
electrical and electronic equipment). The package pins are finished with 100% matte tin.
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WARRANTY
Sirenza Microdevices makes no representations or warranties with respect to the accuracy, utility, or completeness of
the contents of this publication and reserves the right to make changes to specifications and product descriptions at any
time without notice. No license, express or implied, by estoppel or otherwise, to any patents or other intellectual
property rights is granted by this document. The circuits contained in this document are offered as possible applications
only. Particular uses or applications may invalidate some of the specifications and/or product descriptions contained
herein. The customer is urged to perform its own engineering review before deciding on a particular application. Sirenza
Microdevices assumes no liability whatsoever, and disclaims any express or implied warranty, relating to sale and/or
use of Sirenza Microdevices products including liability or warranties relating to merchantability, fitness for a particular
purpose, or infringement of any intellectual property right. Sirenza Microdevices products are not designed for use in
medical, life saving, or life sustaining applications.
If this document is “Advanced”, its contents describe a Sirenza Microdevices product that is currently under
development. All detailed specifications including pinouts and electrical specifications may be changed without notice. If
this document is “Preliminary”, its contents are based on early silicon measurements. Typical data is representative of
the product but is subject to change without notice. Pin out and mechanical dimensions are final. Preliminary
documents supersede all Advanced documents and all previous Preliminary versions. If this document is “Final”, its
contents are based on a characterized product, and it is believed to be accurate at the time of publication. This
document is Preliminary.
© 2007 Sirenza Microdevices Corporation. All rights reserved. All other trademarks are the property of their respective
owners. Products described herein may be covered by one or more of the following U.S. patents: 4,897,611; 4,964,026;
5,027,116; 5,281,862; 5,283,483; 5,418,502; 5,508,570; 5,510,727; 5,523,940; 5,546,017; 5,559,470; 5,565,761;
5,592,128; 5,594,376; 5,652,479; 5,661,427; 5,663,874; 5,672,959; 5,689,167; 5,714,897; 5,717,798; 5,742,151;
5,747,977; 5,754,012; 5,757,174; 5,767,653; 5,777,514; 5,793,168; 5,798,635; 5,804,950; 5,808,455; 5,811,999;
5,818,207; 5,818,669; 5,825,165; 5,825,223; 5,838,723; 5.844,378; 5,844,941. Japan: 2,598,946; 2,619,299;
2,704,176; 2,821,714. Other patents are pending.
Sirenza Microdevices, Inc., 303 S. Technology Court , Broomfield, CO 80021, USA
North America 1- 303-327-3030 z China +86-21-5835-4840 z India +91-80-32902348
www.sirenza.com z [email protected] z [email protected]
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OCT 2007
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EDS-105982 REV P01