MICRO-LINEAR ML2712CH

PRELIMINARY
ML2712 2.4GHz RF Transceiver
GENERAL DESCRIPTION
FEATURES
The ML2712 combined with the ML2713 form a FSK
(Frequency Shift Keying) 2.4 GHz radio chipset. The
ML2712 contains the RF and PLL circuits for a half duplex
radio transceiver solution for IEEE802.11 and other
wireless communication protocols using the 2.4 GHz ISM
band.
The ML2712 is controlled using a three-wire programming
interface and three control lines. The transmit circuits
feature an RF down converter for a transmit frequency
translation loop and a Wideband Phase Detector for a
directly modulated VCO transmitter. An RF down
converter mixer is provided for receive. All frequency
generation circuits are integrated for the RF conversion,
the 1LO VCO and PLL plus a 2LO VCO and PLL for use
in dual conversion radios. In addition the ML2712
contains an 8 bit D/A & Comparator that may be used
together as a tracking A/D for Received Signal Strength
Indication measurement (RSSI).
■
2.4GHz RF Down Converter
■
Programmable 2.2GHz and 236MHz Frequency
Synthesizers
■
External VCO tank circuits for flexibility
■
Compatibility with the OKI MSM7730 and similar
baseband controllers
■
Transmit Wideband Phase Comparator for closed loop
transmitter with >5MHz loop bandwidth
■
PLLs Programmable via 3 wire interface
■
48 pin TQFP 7mm body
■
3.0V to 5.5V operation
APPLICATIONS
■
2.4GHz Frequency Shift Key modulated radios
■
PC Card & Flashcard Wireless Transceivers
■
IEEE802.11FHSS Compatible 1 and 2Mbps Standard
SIMPLIFIED BLOCK DIAGRAM
R. C.
Loop
Filter
ML2731
Bias
Controller
RSSI
Input
ML2712
Transmit
Power
Amplifier
WB
Charge
Pump/WB
Phase
Comp
+
–
DAC
2LO VCO
2LO Loop
Filter &
Tank Circuit
3
3
PLL 2
LPF
Lock
Detect
PLL 1
x2
1LO Loop
Filter &
Tank Circuit
1LO VCO
32MHz
Clock
MUX
ML2713
Tx Regulator
Output
DATASHEET
Reference
Frequency
Input
January, 2000
Baseband
Controller
(e.g., MSM7730B)
PRELIMINARY
ML2712
TABLE OF CONTENTS
General Description .........................................................................................................................................................1
Simplified Block Diagram ................................................................................................................................................1
Features ...........................................................................................................................................................................1
Applications .....................................................................................................................................................................1
Block Diagram ................................................................................................................................................................. 3
Pin Descriptions ...............................................................................................................................................................4
Pin Configuration .............................................................................................................................................................4
Functional Description ..................................................................................................................................................... 7
Introduction ................................................................................................................................................................7
Modes of Operation .........................................................................................................................................................8
Transmit Mode .............................................................................................................................................................8
Standby Mode .............................................................................................................................................................8
Receive Mode ........................................................................................................................................................... 10
Overview of PLLs ...................................................................................................................................................... 11
Operating Mode Control ............................................................................................................................................ 12
Serial Control Bus ...................................................................................................................................................... 13
Electrical Tables ............................................................................................................................................................... 18
Electrical Characteristics .................................................................................................................................................. 18
Absolute Maximum Ratings .............................................................................................................................................. 18
Operating Conditions ....................................................................................................................................................... 18
Physical Dimensions ........................................................................................................................................................ 24
Ordering Information ........................................................................................................................................................ 24
WARRANTY
Micro Linear 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. Micro Linear assumes no liability whatsoever, and
disclaims any express or implied warranty, relating to sale and/or use of Micro Linear products including liability or warranties
relating to merchantability, fitness for a particular purpose, or infringement of any intellectual property right. Micro Linear
products are not designed for use in medical, life saving, or life sustaining applications.
© Micro Linear 2000. is a registered trademark of Micro Linear Corporation. 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.
2
PRELIMINARY DATASHEET
January, 2000
PRELIMINARY
ML2712
BLOCK DIAGRAM
VCC1
RVCC1
VCC2
VCC3
RVCC2
VCC7
VCC4
VCC8
VCC5
VCC6
11
12
15
16
21
23
27
33
34
37
41 2LO
40 2LOB
RSSI 45
1 TPL
RVCC3 42
T2LO 43
QP2
48 RS
38
CONTROL
WB
CHARGE
PUMP
WBCP 35
2LO
VCO
46 LOE
+
2 RSTH
–
WBLD
WB
PHASE
COMP
4
47 TS
8 BIT SERIAL
DAC
2LO CHANGE
PUMP
PRESCALER 14/15
8 DACEN
PRESCALER
CONTROL
LPF
2LO PHASE/
FREQUENCY
DETECTOR
Tx RF
MIXER
2LO 5-BIT
COUNTER
2LO 4-BIT
SWALLOW COUNTER
10 REF
3 LD
TRFI
32
REFERENCE
DIVIDER
GND 31
BG
22
BAND
GAP
REF
7 CLK
ADDRESS
DECODE
6 DATA
1IF 25
1LO 6-BIT
COUNTER
1LO PHASE/
FREQUENCY
DETECTOR
MUX
1IFB 26
1LO CHARGE
PUMP
5 EN
1LO 6-BIT
SWALLOW
COUNTER
MUX
Rx
RF
MIXER
PRESCALER
40/41
PRESCALER
CONTROL
13 QP1
X2
RRFI 30
GND
CONTROL
LOCK
DETECT
1LO
VCO
29
T1LOB 20
T1LO 19
9
14
17
18
24
28
36
39
44
GND
GND
GND
GND
GND
GND
GND
GND
GND
January, 2000
PRELIMINARY DATASHEET
3
PRELIMINARY
ML2712
PIN CONFIGURATION
VCC6
QP2
GND
2LOB
RVCC3
2LO
T2LO
GND
RSSI
LOE
TS
RS
ML2712
48-Pin TQFP (H48-7)
48 47 46 45 44 43 42 41 40 39 38 37
TPL
1
36
GND
RSTH
2
35
WBCP
LD
3
34
WBLD
4
33
VCC5
VCC8
EN
5
32
TRFI
DATA
6
31
GND
CLK
7
30
RRFI
DACEN
8
29
GND
GND
9
28
GND
REF
10
27
VCC1
RVCC1
11
26
VCC4
1IFB
25
1IF
12
VCC7
GND
RVCC2
BG
T1LOB
T1LO
GND
GND
VCC2
VCC3
QP1
GND
13 14 15 16 17 18 19 20 21 22 23 24
TOP VIEW
PIN DESCRIPTIONS
Pin # Signal Name
Power and Ground
11
VCC1
4
9
15
GND
VCC2
16
VCC3
17
27
GND
VCC4
28
34
GND
VCC5
36
GND
37
VCC6
39
23
GND
VCC7
I/O Type
Description
Supply Voltage for CMOS Logic. A bypass capacitor connected with minimum
trace lengths from VCC1 to PCB ground is recommended
Ground for CMOS Logic
Supply voltage for Digital/Analog Converter and Comparator. A bypass
capacitor connected with minimum trace lengths from VCC2 to PCB ground is
recommended
Supply Voltage for 1LO Prescaler and Phase Detector. A bypass capacitor
connected with minimum trace lengths from VCC3 to PCB ground is
recommended
Ground for 1LO Prescaler and Phase Detector
Supply Voltage for RF Amplifier. A bypass capacitor connected with minimum
trace lengths from VCC4 to PCB ground is recommended
Ground for RF Low Noise Amplifier
Supply Voltage for Wideband Transmit PLL Charge Pump. A bypass capacitor
connected with minimum trace lengths from VCC5 to PCB ground is
recommended
Ground for Wideband Transmit PLL Charge Pump. Minimizing the lead trace
length from this GND to PCB ground to reduce inductance and resistance is
recommended
Supply Voltage for 2LO Charge Pump. A bypass capacitor connected with
minimum trace lengths from VCC6 to PCB ground is recommended
Ground for 2LO Charge Pump
Power Supply for 2LO Prescaler and Phase Detector. A bypass capacitor
connected with minimum trace lengths from VCC7 to PCB ground is
recommended
PRELIMINARY DATASHEET
January, 2000
PRELIMINARY
ML2712
PIN DESCRIPTIONS (continued)
Pin # Signal Name
24
33
I/O Type
GND
VCC8
Ground for 2LO Prescaler and Phase Detector
Supply Voltage for Mixers, 1LO Frequency Doubler, and Transmit PLL. A
bypass capacitor connected with minimum trace lengths from VCC8 to PCB
ground is recommended
Ground for Mixers, 1LO Frequency Doubler, and Transmit PLL
29
GND
Regulated Power and Ground
12
RVCC1
14
21
GND
RVCC2
18
42
GND
RVCC3
44
GND
Transmitter Section
32
TRFI
Description
Regulated Bypass Output Supply Voltage for 1LO PLL Charge Pump. A bypass
capacitor connected with minimum trace lengths from RVCC1 to PCB ground is
recommended
Ground for 1LO PLL Charge Pump
Regulated Bypass Output Supply for 1LO Voltage Controlled Oscillator. A
bypass capacitor connected with minimum trace lengths from RVCC2 to PCB
ground is recommended
Ground for 1LO Voltage Controlled Oscillator
Regulated Bypass Output Supply for 2LO Voltage Controlled Oscillator. A
bypass capacitor connected with minimum trace lengths from RVCC3 to PCB
ground is recommended
Ground for 2LO Voltage Controlled Oscillator
I
Transmit RF Input signal. This signal, input to the Transmit Down Converter
Mixer should be AC coupled and matched to the nominal 50Winput
impedance
Transmit Signal Ground. Minimizing the lead trace length from this GND to
PCB ground to reduce inductance and resistance is recommended
Wideband PLL Charge Pump output
31
GND
35
WBCP
O (Analog)
10
REF
I
Reference frequency input to Phase Locked Loops. Requires square wave input
3
LD
O (CMOS)
4
41
WBLD
2LO
O (CMOS)
O
40
2LOB
O
25
1IF
I/O
Lock Detect output. Low output indicates this pin is in open
drain. Two
Phase Locked Loops are frequency locked and requires 10kW pull-up
Wideband PLL Lock Detect open drain output and requires 10kW pull-up
2LO output. Together with 2LOB provides a balanced 2LO output port for
input to Down Converter Mixer on ML2713. Requires 5KW external pull-up
resistor to VCC3 if not connected to ML2713
In Standby Mode, 2LOB and 2LO provide a calibration tone used to calibrate
the ML2713 IF Transceiver
2LOI output. Together with 2LO provide a balanced 2LO output port for input
to Down Converter Mixer on ML2713 Requires 5KW external pull-up resistor to
VCC1 if not connected to ML2713
In Standby Mode, 2LO and 2LOB provide a calibration tone used to calibrate
the ML2713 IF Transceiver
IF Input/Output. In RECEIVE Mode, functions with 1IFB to present a balanced
first IF output port with 340W output impedance. Connection must be AC
coupled. It is recommended that the signal trace connected to this pin be
isolated from other signal or digital control lines to maintain receiver
sensitivity
In TRANSMIT Mode, functions with 1IFB to present a balanced first IF input
port with 340W input impedance. Connection must be AC coupled. It is
recommended that the signal trace connected to this pin be isolated from other
signal or digital control lines to maintain receiver sensitivity
January, 2000
PRELIMINARY DATASHEET
5
PRELIMINARY
ML2712
PIN DESCRIPTIONS (continued)
Pin # Signal Name
26
I/O Type
1IFB
Receiver Section
30
RRFI
6
I/O
IF Input/Output Inverted. In RECEIVE Mode, functions with 1IF to present a
balanced first IF output port with 340W output impedance. Connection must
be AC coupled. It is recommended that the signal trace connected to this pin
be isolated from other signal or digital control lines to maintain receiver
sensitivity
In TRANSMIT Mode, functions with 1IF to present a balanced first IF input port
with 340W input impedance. Connection must be AC coupled. It is
recommended that the signal trace connected to this pin be isolated from other
signal or digital control lines to maintain receiver sensitivity
I
Receive RF Input signal. It is recommended that the nominal input impedance
of 20W on this pin be matched and be AC coupled
Received Signal Strength Indicator input
Digital to Analog Converter high output voltage defined by contents of Control
Register E
RSSI Threshold output. High output indicates RSSI input is greater than TPL.
Digital to Analog Converter output voltage
First Local Oscillator Tank circuit. T1LO and T1LOB provide a balanced pair
for connection to an external parallel inductor/capacitor tank circuit that
determines the frequency of oscillation
Inverted First Local Oscillator Tank circuit. T1LOTB and T1LO provide a
balanced pair for connection to an external parallel inductor/capacitor tank
circuit that determines the frequency of oscillation
Charge Pump output of 1LO Phase Locked Loop. Analog output switches
between VCC2 and ground
Charge Pump output of 2LO Phase Locked Loop charge pump output. Analog
output switches between VCC6 and ground as controlled by the phase detector
in the 2LO PLL
Second Local Oscillator Tank circuit. T2LO and GND (pin 44) provide an
unbalanced pair for a connection to an external parallel inductor/capacitor
tank circuit that determines the frequency of oscillation
Bandgap voltage output. Connection available for bypass capacitor
recommended for noise decoupling from Bandgap voltage reference.
Recommended capacitance value is 10nF connected to ground
45
1
RSSI
TPL
I (Analog)
O
2
RSTH
O (CMOS)
19
T1LO
(Tank Port)
20
T1LOB
(Tank Port)
13
QP1
O
38
QP2
O (Analog)
43
T2LO
O (Analog)
22
BG
I/O (Analog)
Mode Control
46
LOE
47
TS
48
RS
Serial Interface
5
EN
8
DACEN
6
DATA
7
CLK
Description
I (CMOS)
I (CMOS)
I (CMOS)
Local Oscillator Enable
Transmit Switch
Receive Switch
I
I
I
I
Enable serial data
D/A Converter Enable
Serial Data
Clock input for serial data
(CMOS)
(CMOS)
(CMOS)
(CMOS)
PRELIMINARY DATASHEET
January, 2000
PRELIMINARY
ML2712
FUNCTIONAL DESCRIPTION
INTRODUCTION
The ML2712 2.4GHZ RF Transceiver contains all the RF
circuitry, including the phase lock loop (PLL), and the
active VCO circuits, for a half duplex transceiver.
When combined with the ML2713 it enables the
design of a high performance 2.4GHz half duplex
radio with a fast switching time between transmit
and receive modes. This is ideal for applications
such as frequency hopping radio for the IEEE 802.11
FH standard.
The ML2712 Transceiver has four modes of operation; 1)
Standby 2) Transmit 3) Receive and 4) Sleep. The
operating modes of the ML2712 can be programmed
through a parallel control interface or through a serial
interface. Two serial control interfaces are utilized for
programming the PLLs and on chip A/D.
In STANDBY mode all the PLL and VCO circuits are
enabled while all the transmitter and receiver circuits are
disabled. The use of STANDBY mode is recommended
when the PLLs are locking, after the PLL frequencies have
been reprogrammed, or after the IC has been transferred
out of SLEEP mode.
The transmit circuits include a 2.4GHz RF down converter
for transmit frequency translation and a Wideband Phase
Detector that implements a directly modulated VCO
transmitter radio architecture. The receive section of the
ML2712 inlcudes a 2.4GHz RF mixer that down converts
the received RF frequency to the first IF frequency;
nominally 260MHz. All required frequency generation
circuits are integrated on-chip for the RF conversion
including the 1LO VCO and the PLL and 1LO frequency
doubler. Additionally, a second VCO and PLL provide a
2LO output useable in IF circuits in a dual conversion
radio. An 8 bit D/A & Comparator for an RSSI tracking
A/D are also integrated on-chip.
The two local oscillator signals generated in the ML2712
are the 1LO with at a typical frequency in the region of
2.2GHz and the 2LO, with a typical frequency of
236MHz. Both signals are phase locked by the
independently programmable PLLs to a common external
reference frequency. External tank circuits are required
for the 1LO and 2LO VCOs to determine the operating
frequency ranges. The 1LO signal, generated by doubling
the frequency of the 1LO VCO, is used by both the
transmit and receive mixer circuits to down convert the
2.4GHz RF signals. The half-frequency 1LO VCO eases
tank circuit design and minimizes the VCO pulling when
the the radio switches between transmit and receive
modes. The differential output from the 2LO VCO is
provided for use in radio IF circuits such as the ML2713.
A lock detect output indicates when the PLLs are
January, 2000
frequency locked. Programming of the PLL frequency is
performed via a three wire serial interface.
The ML2712 implements a directly modulated VCO
transmitter architecture. The elements of this architecture
include a Power Amplifier, a transmitter VCO, a
transmitter reference generation circuit and a 1IF
Wideband PLL which locks the Transmitter VCO to this
transmit reference signal. The ML2712 does not integrate
the PA but does provide the Wideband PLL and an RF
down-convert mixer, enabling the transmit reference
signal to be generated at a lower frequency. In
TRANSMIT mode the 2.2GHz (nominal) 1LO signal is
used to down-convert the 2.4GHz external transmit VCO
RF signal. The down converted signal is then phase
locked by the on chip wideband phase detector to an
externally modulated signal (Transmit reference IF) and
output to pins 1IFB and 1IF. The output of the Wideband
phase detector controls the transmit VCO frequency (Tx
VCO external to IC) via an external loop filter. For a
typical application, e.g., IEEE802.11 the symbol rate is
1Msymbol/sec. The lock up time is less than 2msec.
enabling a radio designed with the ML2712 to switch
between transmit and receive modes in less than 2msec.
The ML2712 receiver circuits perform the RF down
conversion. A typical receiver design would include the
ML2712, an external LNA and RF filter, an IF filter and
the ML2713 IF Transceiver. In RECEIVE mode, the
ML2712 uses the 1LO signal to down convert the
received 2.4 GHz band signal to a nominal 260 MHz IF.
The received IF signal is output on 1IF and 1IFO pins. By
multiplexing both the transmit and receive signals on one
set of pins, only a single Surface Acoustic Wave (SAW) IF
channel filter is required in the radio design. A SAW filter
with a nominal Gaussian impulse response can be used to
provide modulation filtering of the transmit reference IF
signal. When in receive mode the A/D and Comparator
provide the analog circuits for a tracking A/D converter,
intended for RSSI digitization or clear channel assessment
for "listen before talk" radios.
In SLEEP mode all circuits, except for the central
interface and programming registers, are powered
down to minimize power consumption.
PRELIMINARY DATASHEET
7
PRELIMINARY
ML2712
MODES OF OPERATION
Control
Interface
RSSI
STANDBY MODE
In STANDBY mode all the PLL and VCO circuits are
enabled while all the transmitter and receiver circuits
are disabled. (see Figigure 1) The use of STANDBY
mode is recommended when the PLLs are locking, after
the PLL frequencies have been reprogrammed, or after the
IC has been transferred out of SLEEP mode. The VCO and
PLL circuits are enabled and reach a locked state in 150
usec indicated by an active Lock Detect (LD) signal.The
frequency divide ratio settings defined by Control Word C
and D (see Table 4 ) define the frequencies of the 1LO
PLL and 2LO PLL.
Tx VCO
Tuning
Voltage
WB
Charge
Pump
The ML2712 uses a directly modulated VCO running
at the transmitter frequency to generate the
transmited signal. The VCO is then free of unwanted
spurious signals and has the advantage of requiring
no bandpass filtering for the transmitter signal prior
to or after the Power Amplifier. The transmitter VCO
is phase locked to the center frequency with the
transmitter modulation applied. The modulated signal
is applied directly to the VCO inside the loop
bandwidth of a phase locked loop. To allow
modulation rates in excess of 1Mbps requires a very
wideband phase detector, capable of operating with
loop bandwidths in excess of 5MHz. In this circuit
the noise floor is set by the transmit VCO rather than
by upconvert mixers. The circuits active in TRANSMIT
Mode are shown in Figure 2.
WB
Phase
Comp
2LO Output
To IF Transceiver
2LO VCO
The ML2712 transmitter architecture is shown Figure 3. A
tuning voltage applied to the transmit VCO, operating at
the final transmission frequency, ensures the correct
center frequency before modulation is applied. This closed
loop system, uses a PLL with the Transmit VCO phase
locked to a modulated reference signal (SMOD). The
modulated reference signal is generated at 260MHz. The
signal from the Transmit VCO is down converted with the
1LO signal, then filtered through a bandpass filter. The
output of the filter is fed to the very high-speed phase/
frequency detector Wideband PLL. This compares the
down-converted transmit signal with the modulated
reference signal SMOD.
Any frequency or phase error between SMOD and the
down-converted signal is corrected by changing the
tuning voltage of the transmit VCO. The down-conversion
with the F1LO translates the reference signal SMOD to the
final transmitter frequency.
8
PRELIMINARY DATASHEET
2LO Loop
Filter &
Tank Circuit
PLL 2
LPF
Lock
Detect
Lock Detect
Ref Frequency Input
Rx RF
Input
PLL 1
Rx RF
Input
1LO Loop
Filter &
Tank Circuit
1LO VCO
1IF Input
Output
MUX
ML2712
Active
Disabled
Figure 1. Standby Mode Active Circuits
Control
Interface
Tx VCO
Tuning
Voltage
RSSI
WB
Charge
Pump
RSSI A/D
Comparator
Output
+
Control
DAC
WB
Phase
Comp
–
2LO Output
To IF Transceiver
2LO VCO
2LO Loop
Filter &
Tank Circuit
PLL 2
LPF
DIRECTLY MODULATED TRANSMIT VCO
The transmitter is designed to enable a significant amount
of power to be generated at the required frequency using
a VCO, and is a technique for generating low noise,
phase/frequency modulated transmitters without the need
for bandpass filtering.
–
DAC
x2
TRANSMIT MODE
RSSI A/D
Comparator
Output
+
Control
Lock
Detect
Lock Detect
Ref Frequency Input
Tx RF
Input
PLL 1
1LO Loop
Filter &
Tank Circuit
x2
Rx RF
Input
1LO VCO
1IF Input/
Output
MUX
ML2712
Active
Disabled
Figure 2. Transmit Mode Active Circuits
TRANSMIT SIGNAL
(SMOD + F1LO)
RF DOWN
CONVERTER
LOW PASS
FILTER
FREQUENCY = F1LO
ERROR
CORRECTION
LOOP
FILTER
SMOD +
ERROR SIGNAL
PLL
SMOD = CARRIER FREQUENCY
+ MODULATION
Figure 3. Directly Modulated VCO Transmitter
January, 2000
SMOD
PRELIMINARY
ML2712
MODES OF OPERATION (CONTINUED)
Any modulation on SMOD is duplicated at the final
frequency, provided is it inside the control loop
bandwidth. The spectrum of SMOD and the final output
frequency are shown in Figure 4.
SMOD
TRANSMIT
SIGNAL
PSD
produce a 260MHz (nominal) signal. This signal is fed via
a low pass filter to the Wideband Phase Comparator where
is it compared to the Transmit IF reference signal, supplied
by the ML2713. The Wideband Phase Comparator output
controls the transmit VCO via an external loop filter. The
bandwidth of the Wideband Phase Comparator is high
enough to enable a relatively low tolerance Transmit VCO
to be used.
F1LO
1IF
The Transmit RF input is a single ended design with a
nominal 50 ohms input impedance. The Transmit RF downconverter and Wideband PLL are only enabled in
TRANSMIT Mode.
1IF
FREQUENCY
Figure 4. Simplified Spectrum of Directly
Modulated VCO Transmitter
The PLL loop bandwidth is at least four times that of the
modulation rate. Meeting the IEEE802.11 FHSS
specification for 1Msymbol/sec requires a PLL control
loop bandwidth greater than 4MHz. To achieve the
Wideband PLL dynamics and the RF channel spacing
requirements, the Transmit VCO is down converted with
the 1LO signal (at Frequency F1LO). The RF channel
spacing can be achieved by stepping the 1LO VCO. This
allows the same VCOs and PLLs to be used in both
Transmit and Receive Modes. For typical WLAN operation
the receive frequency and transmit frequency are the same
(between frequency hops). Therefore the 1LO (and 2LO)
frequencies do not require re-tuning when switching from
transmit to receive. As a result the transmit to receive turnround time is very rapid. It is determined by the power on,
settling, and lock up times of the Wideband PLL. For
802.11 FH systems the requirement is less than 2msec.
TRANSMITTER PLL
The transmitter wideband PLL is shown in Figure 5.
An external VCO provides a nominal 2.45GHz signal
which is coupled to the Transmit RF mixer using a
directional coupler or similar external circuit. The
transmiter RF mixer is used to down-convert the transmiter
VCO signal using the frequency doubled 1LO VCO to
VCO AND LOOP FILTER
TO TX POWER
AMPLIFIER
SAW IF
TX RF
MIXER
DIGITALLY
GENERATED
MODULATED
TONE
COUPLER
RX 1LO
VCO AND
PLL
Design of the ML2712 enables the large pull-in frequency
in the Wideband PLL. When TS (Pin 47)is asserted the
Wideband charge pump output is first clamped to midrail. A PFD detector is then used to ensure frequency
lock. Finally the output switches to an XOR detector for
accurate phase tracking. After TS is asserted WBCP is
clamped to a nominal voltage of mid rail of VQWB (the
charge pump supply voltage) for 0.25msec for 16MHz and
32MHz at the reference input, or 0.2msec for 20MHz or
40MHz. This pulls the VCO to mid range.
When the clamp is disabled a phase frequency detector
(PFD) pulls the VCO to frequency lock for 1msec with 16
MHz and 32MHz reference input, or 0.8msec with 20MHz
or 40MHz reference input. This rapidly pulls the VCO to
frequency lock.
If the Wideband bit (Control Word B b11) is set low, the
PFD is then disabled and an XOR phase detector is used
until the TS signal is de-asserted. A factor of four
difference between the PFD and XOR charge pump
currents keeps KD, the phase detector gain, constant. The
PFD charge pump current is nominally 2mA and the XOR
charge pump current is nominally 0.25mA.
ANTI ALIAS
FILTER
TANK
A lock detect output from the Wideband PLL
indicates Frequency Lock. An indication of the
transmitter not locked is required by some regulatory
authorities.
TANK
2LO VCO
AND PLL
The Wideband PLL is designed to ensure the Transmit
VCO is within the pull-in range of the Wideband PLL
(so it will lock when transmitting), to achieve
required lock up time, and to set the loop
bandwidth. The Wideband PLL loop bandwidth
requirement is 4 times the symbol rate at a minimum.
The ML2712 is capable of loop bandwidth greater
than 5MHz. Since the bandwidth of the Wideband PLL
can be >4MHz, the lock up time for 802.11
applications is typically less than 2msec. The maximum
frequency pull-in range for the transmit VCO is
500MHz to ensure that the down-converted signal
passes through the low pass filter.
ML2712
ML2713
Figure 5. Wideband Phase Locked
January, 2000
PRELIMINARY DATASHEET
9
PRELIMINARY
ML2712
MODES OF OPERATION (CONTINUED)
RECEIVE MODE
1LO VCO
The circuits active in RECEIVE Mode are shown in
Figure 6. All the transmitter circuits are normally disabled
Control
in this mode.
RSSI
Interface
The 1LO VCO operates at approximately 1.1GHz, and is
doubled to a final frequency of 2.2GHz. The 1GHZ VCO
signal is connected to the 1LO PLL circuits. The VCO
requires an external differential tank circuit design to
reduce the effects of frequency pulling due to signal
coupling. The tank circuit is tuned by the charge pump
output QP1(Pin 13) using a passive external loop filter.
WB
Charge
Pump
RSSI A/D
Comparator
Output
+
Control
DAC
WB
Phase
Comp
–
2LO Output
To IF Transceiver
2LO VCO
2LO Loop
Filter &
Tank Circuit
PLL 2
LPF
Lock
Detect
Lock Detect
Ref Frequency Input
The active circuitry for the 1LO VCO is a differential
cross-coupled pair providing a negative resistance
across the tank circuit to maintain oscillation. The
tank circuit must provide a DC path to RVCC2 (Pin
21). The layout of this circuit must be kept symmetric
to minimize interference or coupling from other
circuits in the radio.
PLL 1
1LO Loop
Filter &
Tank Circuit
x2
Rx RF
Input
1IF Input/
Output
MUX
ML2712
Active
2LO VCO
1LO VCO
Disabled
Figure 6. Receive Mode Active Circuits
RECEIVE RF DOWN-CONVERTER
The Receive RF input amplifier converts the single
ended RF input to a differential signal which is then
fed to a mixer. The amplifier and mixer combination
down-converts the received RF signal to the receiver
1LO IF (1IF), which is optimized for 260MHz. The
output of the down-converter is differential with
340W of output impedance suitable for low loss
matching to an external SAW IF filter. The 1IF output
ports are bidirectional and are multiplexed with the
transmit reference IF input.
PLL & VCO CIRCUITS
Two independently programmable PLL circuits control the
1LO and 2LO VCO frequencies. These are programmed via
the Serial Control Bus (DATA, CLK, and ENABLE). Program
words are clocked into divider or control circuits when
ENABLE is asserted. The programming is operational
whether the ML2712 is in SLEEP, STANDBY, RECEIVE or
TRANSMIT Mode.
The 2LO VCO requires an external tank circuit and
loop filter. The 2LO VCO is phase locked to provide a
fixed frequency, nominally 236MHz. The differential
pair 2LO (Pin41) and 2LOB (Pin 40) providedrive to
the ML2713. The 2LO differential outputs are from
the collectors of a differential pair that require a pullup to a nominal 2.3V, normally provided by the
ML2713.
A calibration tone added to the 2LO output in
STANDBY Mode is intended for aligning filters and
discriminators in the IF circuits of the ML2713. The
calibration tone is an 8MHz square wave with a
16MHz or 32MHz reference input, or a 10MHz
square wave with af 20MHz or 40MHz reference
input.
The 2LO VCO is a cross-coupled pair, with one base
connected to RVCC3 (Pin 42) (2LO supply voltage). The
other base is connected to an external tank circuit through
T2LO (Pin 43). This design presents a negative impedance
across the tank circuit. Since a dominant oscillation, due
to bond wire inductance and parasitic capacitance on the
PCB, can lead to high frequency oscillation (of the order
of 1GHz), the circuit must be carefully laid out. The 2LO
tank circuit must provide a DC path from T2LO to RVCC3
(Pin 42).
The reference signal, REF (Pin 10) typically from an
external crystal oscillator, is fed to a programmable
reference divider with programmable division ratios of 40,
32, 20 and 16. The reference divider output is fed to both
the 2LO and the 1LO phase/frequency detectors.
The polarity of the charge pump output current pulse is
programmable to give a positive or negative frequency/
voltage control. The value of the current pulses is
programmable via the Serial Control Bus. (See Table 7
and 10)
10
PRELIMINARY DATASHEET
January, 2000
PRELIMINARY
ML2712
MODES OF OPERATION (CONTINUED)
OVERVIEW OF PLLS
Control words programmed via the Serial Control
Bus set the ML2712 PLL reference frequency
divider,and the 2LO PLL and 1LO PLL signal dividers
division ratios. For illustration a simple PLL is shown
in Figure 7.
TUNING
VOLTAGE
CONTROL
VCO
RF OUT
DIVIDE PLL
DIVIDER
BY P
LOOP
FILTER
f = (N ´ ND + NS) ´ (fR/M).
Note that since both PLL signal divider and reference
divider are subject to an extra divide by two stage,
they may be neglected in the equations. However, it
is important to note that the comparison frequency
in MHz in both the 1LO and the 2LO PLL is given by
fC = fR/2M.
DAC AND RSSI COMPARATOR
PHASE
DETECTOR
REFERENCE
DIVIDER
φ
I
The output of the signal divider is compared with the
500 kHz comparison frequency from the reference
divider in the phase detector. In the PLL (Fig. 8) the
tuning voltage to the VCO is adjusted until phase locking
occurs. At this point the VCO frequency in MHz will be
given by the equation:
DIVIDE
BY M
CRYSTAL
OSCILLATOR
REFERENCE
CHARGE
PUMP
Figure 7. Simple PLL
The DAC can be used to generate a voltage output to
control the transmit power in an external power amplifier
(PA). The DAC and Comparator can also be used to form
an RSSI threshold circuit or an RSSI tracking A/D in
conjunction with external baseband circuits. The DAC is
programmed via the Serial Control Bus using either the
DACEN or the EN control line. The DAC may be
programmed at serial clock rates up to 16MHz.
SLEEP MODE
The simplified signal divide by P ( Figure 7) uses a dual
modulus (or swallow pulse) prescaler system.
Figure 8 shows a dual modulus signal divider. This type of
PLL is able to divide by two integers, N and N+1. ND &
NS, are clocked in parallel by pulses from the prescaler,
which is initially set to N+1. The ND & NS registers are
programmed via the Serial Control Bus. The signal divider
ratio achieved by this system is given by the equation:
In SLEEP Mode only the control circuits are active.
These circuits are static CMOS and consume minimal
current when there is no interface activity.
RSD = N ´ ND + NS. ND must be greater than NS.
PRESCALER
FROM
VCO
CLK
N/N+1
IF NS≠0
THEN N+1
ELSE N
NS COUNTER
ND COUNTER
NS COUNTER
MODULUS
ND COUNTER
MODULUS
TO PHASE
DETECTOR
Figure 8. Dual Modulus Signal Divider
January, 2000
PRELIMINARY DATASHEET
11
PRELIMINARY
ML2712
CONTROL INTERFACES
OPERATING MODE CONTROL
A parallel control interface dynamically controls the
four different Modes of operation. The control lines
TS (Pin 47), RS (Pin 48) and LOE (Pin 46) enable the
PLLs, VCOs, transmitter and receiver circuits. The
relationship between this control interface, the
Modes of operation and the functioning of the
circuits are described in Table 1. The function of this
control interface can be duplicated via the Serial
Control Bus, and the circuits enabled in STANDBY,
RECEIVE and TRANSMIT can be programmed via the
Serial Control Bus.
RS
High
TS
High
LOE
High
Mode
IC Status
SLEEP
All radio circuits are off. Static CMOS control circuits are active, consuming
minimal current but permitting the register settings to be changed via the baseband
controller IC. Registers store power-up default or previously programmed values on
serial control lines. The baseband IC may configure the radio, while the radio is
neither transmitting nor receiving data, but the ML2712 will maintain the last
programmed values. Note that in SLEEP Mode the operating Mode control may be
overridden by the Serial Control Bus if parallel control interface is not required.
High
High
Low
STANDBY
Only the VCO and PLL circuits are enabled in this mode and will be locked within
150msec. This will be flagged by an LD (lock detect) signal. The frequency divide
ratio settings will cause the two PLLs to lock to the desired frequencies. In this
mode the 2nd LO output signal can have a calibration signal added to the 2LO
VCO signal. This calibration signal is used for discriminator alignment on the
ML2713. The 8 bit DAC and associated comparator circuit are enabled.
Low
High
Low
RECEIVE
The Receive RF down-converter, 1LO PLL & VCO, 2LO PLL & VCO, RSSI DAC,
and RSSI comparator are all enabled, although for maximum flexibility any of these
circuits could be disabled via the Serial Control Bus.
High
Low
Low
TRANSMIT
The Transmit RF down-converter, Wideband PLL, 1LO PLL & VCO, 2LO PLL &
VCO, and RSSI D/A are all enabled, although for maximum flexibility any of these
circuits could be disabled via the Serial Control Bus
Table 1. Operating Mode ControlStates
12
PRELIMINARY DATASHEET
January, 2000
PRELIMINARY
ML2712
CONTROL INTERFACES (CONTINUED)
SERIAL CONTROL BUS
pulses are active and either may be used to latch
control words, although not simultaneously. In this
mode DACEN will write data to the 8-bit DAC
regardless of the address data. The EN pulse will
continue to operate as described for DCE set to 0.
The ML2712 contains two 3-wire serial control
interfaces. They have common clock and data, but
separate latch enable controls (EN & DACEN). The EN
signal programs the registers that determine the
operation of the PLLs, VCOs and DAC, and
determines which circuits are active in STANDBY,
RECEIVE and TRANSMIT Modes. The DACEN signal is
dedicated to DAC programming only. Serial bus
control is active in all operating Modes. The serial
control interface overrides the parallel mode control
interface. See Table 2 and Figure 9.
The ML2712 default power up condition is designed
for normal operation. At power up the registers are
programmed as in Table 4. The user may adjust the
mode of operation for specific tasks by programming
the control register settings immediately after power
up, or at an appropriate time during operation. Note
that address field 000 is reserved for test modes and
should not be programmed in normal operation.
All DATA bits are clocked into the ML2712 while EN
or DACEN is low and loaded into the addressed latch
on the low to high trailing edge of the EN or DACEN
pulse. The serial bus control register only retains the
last 16 bits of data that follow either the EN or DACEN
pulse. The data latches are fully static CMOS and use
minimal power when the Serial Control Bus is inactive.
tS
tR
tH
tCK
tF
tL
CLK
tSE
DATA
All Serial Control Bus words are entered data MSB first.
The word is made up of data and address fields. The data
field is the leading 13 bits and the last 3 bits are the
address field (see Table 3). The address field determines
the destination register for the data field. There are 5
control registers (CONTROL WORDs A, B, C, D, and E)
defined in Table 4. When data is latched by a DACEN
pulse the address field is ignored and the data field is
always used to program the 8-bit DAC. In Tables 3 and 4
the left-most bit isalways the MSB.
MSB
tEW
EN &
DACEN
Figure 9. Control Bus Timing
Parameter
Min
Typ
Max
Units
15
ns
CLK
EN or DACEN are enabled to latch data into the DAC
register as determined by the DCE control bit, b4 in
Control Word B. When DCE is set to 0, the default
power up state, the EN latch enable pulse is active
and the DACEN pulse is disabled. In this state a rising
edge on EN will write data to the 8-bit DAC when the
address field is correct. Other control words may be
written using different address fields as shown in
Table 4. When DCE is set to 1 both DACEN and EN
tR
Rise time
tF
Fall time
tCK
Period
50
15
ns
ns
tEW
Pulse width
2
ns
tL
Falling edge delay
15
ns
tSE
Rising edge setup
15
ns
tS
Data-to-Clock Setup
15
ns
tH
Data-to-Clock Hold
15
ns
EN & DACEN
DATA
Table 2. Three Wire Bus Interface Timing Characteristics
Field
bit
DATA
ADDRESS
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
Data
Data
Data
Data
Data
Data
Data
Data
Data
Data
Data
Data
Data
Add
Add
Add
12
11
10
9
8
7
6
5
4
3
2
1
0
3
2
1
Function
Table 3. Format of Serial Control Bus data
January, 2000
PRELIMINARY DATASHEET
13
PRELIMINARY
ML2712
CONTROL INTERFACES (CONTINUED)
Data
Control Word A
Power Up Default
Control Word B
Power Up Default
b0
b1
b2
b3
b4
b5
b6
b7
b8
b9
b10
b11
b12
VC1
VC2
PLL1
PLL2
CP1
CP2
PP1
PP2
LD1
LD2
PPW
PB
x
1
1
1
1
1
1
1
1
1
1
1
1
x
TX
RX
LBC
DAC
DCE
COM
CI1
CI2
CI3
CI4
CAL
WB
x
0
0
0
1
0
1
1
1
1
1
1
1
x
MSB 1LO ND1 Counter LSB
Control Word C
Power Up Default
1
1
MSB
Control Word D
0
1
1
MSB 1LO NS1 Swallow Counter LSB
0
2LO ND2 Counter
0
1
0
1
2LO NS2 Counter
MSB
Power Up Default
1
0
0
0
0
Control Word E
x
x
x
x
MSB
Power Up Default
x
x
x
x
0
0
b13
b14
b15
0
0
1
0
1
0
x
0
Address
x
Reference Div.
0
x
1
1
Address
LSB
1
1
0
0
0
0
8-bit DAC Voltage
0
0
0
0
0
0
1
x
LSB
x
0
x
1
0
0
Address
1
0
1
Table 4. Control Word Settings on the Serial Control Bus
Control Bit in CONTROL WORD A
ML2712 Circuits Enabled
1LO Charge
Pump
2LO Charge
Pump
x
x
x
x
x
x
x
x
ON
x
x
x
x
x
x
ON
x
x
x
x
x
x
x
ON
x
x
1
x
x
x
x
x
ON
1
1
V C1
VC2
PLL1
PLL2
CP1
CP2
1LO VCO
2LO VCO
1LO PLL
0
0
0
0
0
0
1
x
x
x
x
x
ON
x
x
x
1
x
x
x
x
x
ON
x
x
1
x
x
x
x
x
x
x
1
x
x
x
x
x
x
1
x
x
x
x
1
1
1
1
2LO PLL
ALL OFF
ALL ON (DEFAULT POWER UP CONDITION)
Table 5. VCO, PLL and Charge Pump Power Control Modes
CONTROL WORD A
Control Word A enables the VCOs, PLL dividers, PLL
charge pumps and voltage reference circuits;
programs the polarity of PLL charge pumps; and
programs the function of the Lock Detect (LD)
output.
oscillators to down convert the 2450 MHz ISM Band RF
signal. (Table 5).
All these circuit components are enabled individually
using CONTROL WORD A as defined in Table 4. For
the PLLs to operate, all control bits must be set to 1.
Control Bits VC1, VC2, PLL1, PLL2, CP1, CP2
Two frequency synthesizers, 1LO and 2LO, each
contain a VCO and a PLL. This dual conversion
superheterodyne receiver uses the two local
14
PRELIMINARY DATASHEET
January, 2000
PRELIMINARY
ML2712
CONTROL INTERFACES (CONTINUED)
Control Bits LD1 & LD2
Control Bit PB
The PLLs indicate their lock status using the Lock
Detect output (LD Pin 3). Control bits LD1 & LD2
program the indication of frequency lock on 1LO, 2LO, or
both 1LO and 2LO, as shown in Table 6.
A band-gap voltage reference is used to control bias
levels. Control Bit PB in CONTROL WORD A controls
this internal voltage reference. For any circuits to
operate, other than the control interfaces, this bit
must equal 1.
Control Mode
LO Status
LD1
LD2
1LO
CONTROL WORD B
2LO
LD Pin output
Mode of Operation
Output disabled
0
0
x
x
1
0
1
unlocked
unlocked
0
0
1
locked
1
unlocked
locked
locked
locked
unlocked
0
0
1
1
0
unlocked
unlocked
0
1
0
locked
unlocked
0
1
1
0
0
unlocked
locked
locked
locked
1
1
1
1
unlocked
unlocked
0
1
1
locked
unlocked
0
1
1
1
1
unlocked
locked
locked
locked
0
1
1LO lock indication
Control Bits TX, RX & LBC
2LO lock indication
2LO & 1LO lock
indication
Table 6. Lock Detect Mode
Control Bits PP1, PP2 & PPW
In each PLL a charge pump or switched current
source either sinks or sources a current pulse
depending on the error signal at the phase detector.
Iif the divided VCO frequency at the phase detector
is greater than the reference frequency, the charge
pump will source a current pulse. The current pulse
is fed to an external loop filter serving as an
integrator or current reservoir. The result is the
voltage across the loop filter and the tuning voltage
to the VCO increasing or decreasing depending on
the loop filter being referenced to ground or the
power supply. The polarity of charge pumps within
the PLL and transmit wideband PLL (WBPLL) may be
programmed using CONTROL WORD A as shown in
Table 7. The charge pump current settings in Table 10
assume that the external loop filter is reference to ground.
Control Bit in CONTROL
WORD A
PP1
PP2
PPW
Control Word B changes the control mode in which
ML2712 operates. CONTROL WORD B may also be
used to program charge pump current level and
enable the DAC, Comparator & calibration circuits.
The Mode of operation can be controlled via the serial
interface (which disables the parallel operating mode
interface). This option reduces the pin count requirement
for a baseband controller. Individual circuit blocks may
all be toggled on or off using control words. Extra control
mode bits, TX & RX in CONTROL WORD B, are provided
to enable transmit and receive switching via the Serial
Control Bus interface. These control bits are enabled by
the LBC control bit as shown in Table 8. Individual circuit
blocks may be controlled by the Serial Control Bus control
interface during LBC = 1 mode. When LBC = 1 the
control lines TS (pin 47) and RS (pin 48), are ignored and
the Mode of operation is determined by the TX and RX bit
in Control Word D.
Control Bit in
CONTROL WORD B
Control Status
TX
RX
LBC
X
X
0
Parallel Control Interface
(Default Power on condition)
0
0
1
Serial control - Tx & Rx circuits off
0
1
1
Serial control - Rx circuits on
1
0
1
Serial control - Tx circuits on
1
1
1
Serial control - Tx & Rx circuits off
Table 8. Parallel Control Over-Ride Using LBC Bit
ML2712 Charge Pump Polarity
1LO Charge pump polarity
Frequency signal > Frequency
ref. Pump high
Frequency signal > Frequency
ref. Pump low
1
x
x
0
x
x
x
1
x
x
x
0
x
x
2LO Charge pump polarity
WBPLL Charge pump polarity
x
x
x
x
Frequency signal > Frequency
ref. Pump high
Frequency signal > Frequency
ref. Pump low
x
x
1
x
x
x
x
0
x
x
x
x
Frequency signal > Frequency ref.
Pump high
Frequency signal > Frequency ref.
Pump low
Table 7. Charge Pump Polarity
January, 2000
PRELIMINARY DATASHEET
15
PRELIMINARY
ML2712
CONTROL INTERFACES (CONTINUED)
Control Bits DAC, COM & DCE
Control Bits CI1, CI2, CI3, CI4
The DAC and comparator may be used as a tracking ADC
circuit. In normal operation these circuits are available in
TRANSMIT, RECEIVE & STANDBY operating Modes.
However, independent control of the comparator and DAC
is available via control bits as shown in Table 9. There are
two other modes available to program the DAC. When
DCE in CONTROL WORD B is set to 0, EN is active and
DACEN is disabled. With DCE at 1 both the DACEN and
EN pins are active. DACEN and EN cannot be
simultaneously low. With DCE at 1 a rising edge on
DACEN will write data to the 8-bit DAC regardless of the
address data.
The PLLs each contain a charge pump. The magnitude of
the current in these pumps may be controlled as defined
in Table 10. The recommended values for best phase
detector performance are [CI1,CI2]=[1,0] or [1,1] and
[CI3,CI4] = [1,0] or [1,1].
Control Bit in
CONTROL
WORD B
Circuits Enabled
DAC
COM
1
1
DAC & Comparator on
(Default power up state)
0
1
DAC off, Comparator on
1
0
DAC on, Comparator off
0
0
DAC & Comparator off
Control Bit CAL
The ML2713 companion to the ML2712 contains selfaligning filter and discriminator circuits. The alignment of
these circuits is designed to take place when the ML2712/
ML2713 chipset is in STANDBY Mode ( Table 1). Under
power up default conditions in STANDBY Mode the
ML2712 provides an 8 MHz calibration tone to the
ML2713 via the 2LO output (pins 2LO & 2LOB). This will
happen while the 1LO and 2LO local oscillators are phase
locking. However, the CAL tone may be disabled using
CONTROL WORD B (See Table 11).
Table 9. Control of ML2712 DAC & Comparator
Control Bit in CONTROL WORD B
Charge Pump Setting
CI1
CI2
CI3
CI4
1LO Charge pump current (mA) 2LO Charge pump current (mA)
0
0
x
x
0.25
x
0
1
x
x
0. 5
x
1
0
x
x
1
x
1
1
x
x
2
x
x
x
0
0
x
0.25
x
x
0
1
x
0.5
x
x
1
0
x
1
x
x
1
1
x
2
Table 10. Charge Pump Currents
CAL bit in CONTROL
WORD B
Calibration Mode
WB bit in CONTROL
WORD B
Calibration Mode
0
Calibration output to 2LO disabled
1
Wideband PLL phase Dual PFD & XOR mode
1
Calibration tone to 2LO port enabled (Default
power up mode)
0
Wideband PLL phase In XOR only mode
Table 11. Control of Calibration Tone Generation
16
PRELIMINARY DATASHEET
Table 12. Control of CalibrationTone Generation
January, 2000
PRELIMINARY
ML2712
CONTROL INTERFACES (CONTINUED)
CONTROL WORD C
RSSI INPUT
VOLTAGE
2LO ND & NS counters are denoted as ND2 & NS2.
The binary weighted modulus values are loaded
using CONTROL WORD C as shown in Table 13. The
prescaler used in the 2LO PLL is a 14/15 dual modulus
type giving the 2LO frequency in MHz as f2LO = (14 ´
ND2 + NS2) ´ (fREF /M).
+
BASEBAND
IC
TPL
OUTPUT
VOLTAGE
8
SCALING
AMPLIFIER
The reference divider ratio M is also set in CONTROL
WORD C (Table 4)
Control Bit
CONTROL WORD C
Reference Division Ratio M
b9
b10
b11
0
0
0
16
0
0
1
32 (Power up Default)
0
1
0
20
0
1
1
40
Alternatively, the DAC may be programmed with a
threshold value that when exceeded triggers the baseband
IC into receive mode. In this mode the DAC and
Comparator are used to provide the necessary circuits for
Clear Channel Assessment (CCA) as defined in IEEE
802.11. Figure 11 shows the relationship between RSSI
DAC code (in decimal) programmed into ML2712 via
CONTROL WORD E and the DAC RSSI voltage threshold.
250
VCCD = 5.0V
VCCA = 3.3V
200
DAC CODE
The 1LO PLL is a dual modulus type as described
above. 1LO ND & NS counters are denoted in
ML2712 as ND1 & NS1. Modulus values are binary
weighted and are loaded using CONTROL WORD D as
shown in Table 4. The prescaler used in the 1LO PLL
is a 40/41 dual modulus type giving the 1LO
frequency in MHz as
CONTROL
WORD D
[B4...B11]
8 BIT D/A
Figure 10. Charge Pump Polarity
Table 13. Reference Division Ratio
CONTROL WORD D
RSTH
–
150
100
50
0
1.9
2.1
2.3
2.5
2.7
2.9
3.1
3.3
RSSI THRESHOLD VOLTAGE (V)
Figure 11. Parallel Control Over-Ride Using LBC Bit
CONTROL WORD E
The 8-bit DAC and Comparator form a tracking
Analog-to-Digital converter (ADC) intended to
connect to the RSSI (Receive Signal Strength
Indicator) on the ML2713.
The tracking ADC is represented in Figure 10.
CONTROL WORD E is used to program a voltage into
the 8-bit DAC setting up a voltage on the inverting
terminal of the Comparator. If the RSSI voltage
exceeds that on the DAC then RSSITH signals logic
high.
Typically, a baseband IC will be used to program RSSI
values into the ML2712 corresponding to a known
receive signal level. The RSTH value (high/low) is
sensed by the baseband IC to determine if the signal
strength threshold has been exceeded. By
successively programming the 8-bit DAC using CONTROL
WORD E the baseband IC can measure the RSSI voltage
closely.
The DAC also has a general purpose use. The DAC voltage
programmed using CONTROL WORD E is fed to scaling
circuit before appearing externally at TPL. While the DAC
output is suitable for general use, a likely use for the
voltage is for transmit power control. In this mode of
operation the DAC voltage corresponding to the required
transmitter output power can be programmed before
transmit operation. The relationship between TPL voltage
versus DAC programming is shown in Figure 12.
250
VCCD = 5.0V
VCCA = 3.3V
LOAD ON TPL = 1MΩ
IN PARALLEL WITH 15pF
200
DAC CODE
f1LO = (40 ´ ND1 + NS1) ´ (fREF /M).
150
100
50
0
0.5
1.0
1.5
2
2.5
3
TPL VOLTAGE (V)
Figure 12. Control of ML2712 DAC Comparator
January, 2000
PRELIMINARY DATASHEET
17
PRELIMINARY
ELECTRICAL CHARACTERISTICS
ABSOLUTE MAXIMUM RATINGS
ML2712
OPERATING CONDITIONS
Absolute maximum ratings are those values beyond which
the device could be permanently damaged. Absolute
maximum ratings are stress ratings only and functional
device operation is not implied.
Commercial Temperature Range .................... 0°C to 70°C
Extended Temperature Range ..................... -20°C to 70°C
VCC1 Range .................................................3.0V to 5.5V
VCC2Range ................................................ 3.3V ± TBD%
Thermal Resistance (qJA) (Note 2) ...................... 100°C/W
VCC1 ........................................................................................... 6.0V
VCC2, RVCC1, VCC3, RVCC2, VCC4, VCC8 , VCC5 ,
VCC6 , RVCC3 ........................................ -0.3V to VCC1 + 0.3V
Storage Temperature Range ..................... –65°C to 150°C
Lead Temperature (Soldering, 10s) .......................... 260°C
ELECTRICAL TABLES
Unless otherwise specified, VCC1 = 5V, VCC2, RVCC1, VCC3, RVCC2, VCC4, VCC8, VCC5, VCC6, RVCC3 = 3.3V,
TA = Operating Temperature Range. (Note 1)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
POWER CONSUMPTION TRANSMIT AND RECEIVE RF
All Circuits, Sleep Mode
DC Connected
10
µA
Supply Current, Standby Mode
61
mA
Supply Current, Receive Mode
66
mA
Supply Current, Transmit Mode
94
mA
Input High
V CCD
V
Output Low
0
V
INTERFACE LOGIC LEVELS
Input Bias Current
All States
±5
µA
Input Capacitance
(Not Tested)
4
pF
Lock Detect Output Low
ISINK = 0.5mA
0.4
V
Time, Sleep to Standby, PLLs Locked
(Note 3)
From LOE Asserted to 1LO and 2LO
Within 20KHz of Final Frequency
150
µs
PLL Lockup Time, Standy & Receive
(Note 3)
From EN Asserted to 1LO and 2LO
Within 20KHz of Final Frequency
150
µs
Time, Standby to Receive
Time from RS Asserted to Receive
RF Down Converter Enabled
1
µs
Time, Standby to Transmit
Time from TS Asserted to Transmit
RF Down Converter and Wideband
PLL Enabled
1
µs
Time, Receive to Transmit
From RS de-asserted, TS asserted and
Wideband PLL & Transmit Down
Converter Ready
1
µs
MODE CONTROL PINS
ELECTRICAL TABLES (CONTINUED)
18
PRELIMINARY DATASHEET
January, 2000
PRELIMINARY
ML2712
ELECTRICAL TABLES (CONTINUED)
SYMBOL
PARAMETER
CONDITIONS
Time, Transmit to Receive
MIN
From TS de-asserted, RS asserted to
Receive RF Mixer Ready
TYP
MAX
UNITS
1
µs
–1.5
dB
15
dB
–9.5
dBm
0
dBm
RECEIVE RF MIXER
Receive RF Mixer Gain
Receive RF Mixer Noise Figure
Receive RF Mixer Input 1dB Gain
Compression Point
In-band Tone
Receive RF Mixer Input IP3
Receive RF Input Impedance
Nominal, single ended into RRFI,
1.5 pF shunt capacitor
external matching
50
W
Receive RF Output Impedance
Differential
340
W
Receive RF Mixer Turn on Time.
1
µs
Receive RF Mixer Turn off Time.
1
µs
RECEIVE 1LO VCO AND 1LO PLL
1LO Output Frequency
1060
MHz
Minimum Q for Performance
Required of 1LO
Unloaded Q of Tank Circuits.
10
1LO, Integrated Noise, out of Receive
1MHz
–45
dBc
Band in 1MHz Band at Offsets from
2MHz
–50
dBc
Carrier. Integrated +/-500kHz about
3MHz
–55
dBc
Comparison Frequency
>3MHz
–55
dBc
500
kHz
1LO PLL Reference Frequency at Phase
Detector
1LO Division Range
REF
1130
2000
2260
Integer
1LO Lock up Time for any Valid Frequency From LE asserted. Maximum charge
Change
pump current
150
µs
1LO Lock up Time from Sleep
(Note 3)
PLL Dividers Programmed,
Maximum Charge Pump Current
150
µs
Reference Signal Input Level
Single Ended, Square Wave, Peak
V CCA
mV
236
MHz
10
kHz
–50
dBc
2LO VCO AND PLL
2LO frequency
Frequency Pulling
Switching among Transmit,
Receive and Standby.
Phase Noise Double Sideband, Integrated
from 5kHz to 600kHz (Note 4)
2LO, Integrated Noise, out of Receive
1MHz
–55
dBc
Band in 1MHz Band at Offsets from
2MHz
–60
dBc
Carrier. Integrated ±500kHz about
3MHz
–65
dBc
Frequency
>3MHz
–65
dBc
January, 2000
XX/XX/99 Printed in U.S.A.
PRELIMINARY DATASHEET
19
PRELIMINARY
ML2712
ELECTRICAL TABLES (CONTINUED)
ELECTRICAL TABLES (CONTINUED)
SYMBOL
PARAMETER
Output Signal level, Differential
CONDITIONS
MIN
200W Balanced Load
Reference Frequency
2LO PLL Reference Frequency at Phase
Detector
2LO Division Ratio
Assumes 1MHz Comparison
Frequency for 2LO
2LO Lock up Time (Note 4)
From Enable 2LO to Within 10kHz
of Final Frequency
TYP
MAX
UNITS
30
mV
32 or 16
MHz
500
kHz
216
256
Integer
100
µs
8
bits
±0.5
LSB
±1
LSB
Temperature coefficient
3
PPM/ºC
Offset error
±3
LSB
DAC
Resolution
Relative accuracy
Differential Non-linearity
Monotonic under all Conditions
RSSI Voltage Conversion Range
Sensed by RSTH Comparator, DAC
Code 0 to Code 255
2.0
3.2
V
TPL Output Voltage Range
Load = 1MW, DAC Code 0 to
Code 255
0.7
2.8
V
5
mA
0.15
V/µs
500
ns
50
dB
Output High
V CCD
V
Output Low
0.0 ±0.3
V
Output Sink/Source Capability
4
mA
Input Offset Error
2
mV
500
ns
Input Voltage Range
2
V
RSSI Input Bias Current
20
µA
–10
dBm
1
µs
Maximum Difference Frequency Between
1LO ´ 2 and Transmit VCO (Note 5)
500
MHz
Minimum Difference Frequency Between
1LO ´ 2 and Transmit VCO (Note 5)
100
MHz
Short Circuit Current
Output slew rate
Output Settling Time
To within ½ LSB
Signal to Noise and Distortion
COMPARATOR
Input to Output Propagation Delay
Input to Output High
and Input to Output Low
TRANSMIT RF MIXER AND WIDEBAND PHASE COMPARATOR
Transmit RF Input Signal Power
Transmit RF Mixer and Wideband
Phase Comparator Turn on Time
20
PRELIMINARY DATASHEET
January, 2000
PRELIMINARY
ML2712
ELECTRICAL TABLES (CONTINUED)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Frequency of Reference Signal
Modulation on Reference
240
260
280
MHz
Transmitter Phase Noise (Note 6)
External Transmit VCO Locked
to the ILO
–126
dBc/Hz
Transmitter Phase Noise in 1MHz
1MHz
–50
dBc
Band at Offsets from Carrier. Integrated
2MHz
–66
dBc
±500kHz about Frequency.
3MHz
–66
dBc
>3MHz
–66
dBc
2
µs
3
kHz
Lock up Time, from any Starting Transmit
1LO and Receive 1LO Frequency
to <20kHz (Note 6)
Modulation Error (Note 7)
1MSymbol/s 2GFSK or 4GFSK to
Ideal GFSK
Note 1: Limits are guaranteed by 100% testing, sampling, or correlation with worst case test conditions.
Note 2: qJA is measured with the component mounted on the Evaluation PCB in free air.
Note 3: Phase noise and lock up time tested with 1LO VCO Q = 10, kVCO = 100MHz/V. Phase noise measured at IF output by down converting a 2450MHz signal to a
260MHz IF. Input signal at –20dBm. Charge pump current set to default.
Note 4: Measurements taken with 236MHz 2LO. Tank circuit of 2LO VCO Q = 8, kVCO = 40MHz/V.Charge pump current set to maximum.
Note 5: This is proven by design, it is not tested in production.
Note 6: Measured with an external Transmit VCO, with Q = 15, kVCO = 120MHz/V, output power 0dBm, –10dBm input to TS272. Reference signal is a 260MHz sine
wave.
Note 7: Measured with an external Transmit VCO, with Q = 15, kVCO = 120MHz/V, output power 0dBm, –10dBm input to TS272. Reference is a 260MHz center
frequency signal, modulated with 4GFSK. Error is measured relative to the reference signal at the center of the data symbol.
January, 2000
PRELIMINARY DATASHEET
21
PRELIMINARY
ML2712
PHYSICAL DIMENSIONS
Package: H48-7
48-Pin (7 x 7 x 1mm) TQFP
0.354 BSC
(9.00 BSC)
0.276 BSC
(7.00 BSC)
0º - 8º
0.003 - 0.008
(0.09 - 0.20)
37
1
PIN 1 ID
0.276 BSC
(7.00 BSC)
0.354 BSC
(9.00 BSC)
0.018 - 0.030
(0.45 - 0.75)
25
13
0.020 BSC
(0.50 BSC)
0.048 MAX
(1.20 MAX)
0.007 - 0.011
(0.17 - 0.27)
SEATING PLANE
0.037 - 0.041
(0.95 - 1.05)
ORDERING INFORMATION
PART NUMBER
TEMPERATURE RANGE
PACKAGE
ML2712CH
0°C to 70°C
48 Pin TQFP 7mm body
ML2712EH
-20°C to 70°C
48 Pin TQFP 7mm body
Micro Linear Corporation
2092 Concourse Drive
San Jose, CA 95131
Tel: (408) 433-5200
Fax: (408) 432-0295
www.microlinear.com
DS2712-01
22
PRELIMINARY DATASHEET
January, 2000