MAXIM MAX3570

19-0067; Rev 0; 2/05
KIT
ATION
EVALU
LE
B
A
IL
A
AV
HI-IF Single-Chip Broadband Tuners
The MAX3570/MAX3571/MAX3573 low-cost, broadband, dual-conversion tuner ICs are designed for use
in digital television receivers. Each IC integrates all
necessary RF functions, including an integrated HI-IF
filter, fully integrated VCOs, and an integrated IF VGA.
The operating frequency range extends from 50MHz to
878MHz while providing over 60dB RF/IF gain-control
range. The MAX3570/MAX3571 have an IF frequency
centered at 44MHz, while the MAX3573 has an IF output centered at 36MHz.
These devices include a variable-gain front-end, achieving an overall 8dB noise figure. A dual synthesizer generates both local oscillator (LO) frequencies, providing
superior phase noise performance of -86dBc/Hz at
10kHz. The integrated HI-IF filter achieves 55dBc (typ) of
image rejection. Only an IF SAW filter, passive loop filters, and a crystal are needed to complete a single-chip
tuner. Device programming and configuration are
accomplished with a 3-wire serial interface for the
MAX3570, and with a 2-wire serial interface for the
MAX3571/MAX3573.
The MAX3570/MAX3571/MAX3573 are available in a
48-pin QFN-EP package and are specified for the commercial (0°C to +70°C) temperature range.
Features
♦ Fully Integrated HI-IF Filter
♦ Fully Integrated VCOs, No External Components
or Traces
♦ Low 8dB Noise Figure
♦ High Linearity—Greater Than 54dBc, CSO, CTB,
X-MOD
♦ Industry’s Smallest Footprint
♦ Superior Phase Noise for 256-QAM, 8-VSB, and
COFDM
Ordering Information
PART
TEMP RANGE
PIN-PACKAGE
MAX3570CGM
0°C to +70°C
48 QFN-EP*
MAX3571CGM
0°C to +70°C
48 QFN-EP*
MAX3573CGM
0°C to +70°C
48 QFN-EP*
*EP = Exposed paddle.
Pin Configurations/
Functional Diagrams
IFOUT2+
VCC
IFVGA
IFIN-
IFIN+
VCC
46
IFOUT2-
47
GND
48
VCC
Cable Modems
RFVGA
ATSC Digital Terrestrial Receivers
BIAS
DVB-C Digital Terrestrial Receivers
LNABIAS
Applications
45
44
43
42
41
40
39
38
37
VCC 1
DOCSIS/EURO DOCSIS Cable Modems
36 IFOUT1-
RFIN+ 2
ITU J.83 Digital Set-Top Boxes
35 IFOUT1+
MAX3570
RFIN- 3
34 GND
HI-IF
FILTER
GND 4
Selector Guide
33 VCC
VCC 5
32 GND
GND 6
31 VCC
VCC 7
30 TUNE2
TUNE1 8
29 LOCFLT2
LOCFLT1 9
PART
SERIAL INTERFACE
IF CENTER
FREQUENCY
(MHz)
28 GND
GND 10
I.C. 11
27 VCC
DUAL SYNTHESIZER
26 CPOUT2
3-WIRE SERIAL
INTERFACE
19
20
21
22
23
24
OSCIN
GND
GND
36
18
OSCOUT
2-Wire
17
GND
MAX3573
16
VCC
44
15
CPOUT1
2-Wire
14
I.C.
MAX3571
25 VCC
13
DIV/LD
44
VCC
3-Wire
SDA
MAX3570
SCL
CS 12
Pin Configurations/Functional Diagrams continued at end
of data sheet.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at
1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.
1
MAX3570/MAX3571/MAX3573
General Description
MAX3570/MAX3571/MAX3573
HI-IF Single-Chip Broadband Tuners
ABSOLUTE MAXIMUM RATINGS
VCC to GND ...........................................................-0.3V to +5.5V
IFIN_, IFOUT1_, IFOUT2_, RFIN_, TUNE_,
LOCFLT_, CPOUT_, OSCIN, OSCOUT,
IFVGA, RFVGA, BIAS, LNABIAS,
ADDR_, CS, SCL, SDA, DIV/LD...............-0.3V to (VCC + 0.3V)
Continuous Power Dissipation (TA = +70°C)
48-Pin QFN (derate 27mW/°C above +70°C) ............2162mW
Operating Temperature Range...............................0°C to +70°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
CAUTION! ESD SENSITIVE DEVICE
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
DC ELECTRICAL CHARACTERISTICS
(MAX357_ EV kit, VCC = +4.75V to +5.25V, RBIAS = 5.9kΩ ±1%, no AC signal applied, TA = 0°C to +70°C, unless otherwise noted.
Typical values are at VCC = +5.0V, TA = +25°C, unless otherwise noted.) (Note 1)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
5.25
V
SUPPLY VOLTAGE AND SUPPLY CURRENT
Supply Voltage
Supply Current
RF and IF VGA Input Bias Current
RF and IF VGA Control Voltage
4.75
At TA = +25°C, VRFVGA = +3.0V
320
At TA = +70°C, VRFVGA = +0.5V
VRFVGA = VIFVGA = +0.5V and +3.0V
Maximum gain
385
-50
+50
3
Minimum gain
0.5
mA
µA
V
LOGIC INTERFACE
Input-Logic Low (VIL)
0.9
Input-Logic High (VIH)
2.3
Input Logic Current
-10
Output-Logic Low
Sink current = 3mA
Output-Logic High
Source current = 3mA
2
+10
0.4
2.8
_______________________________________________________________________________________
V
V
µA
V
V
HI-IF Single-Chip Broadband Tuners
(MAX357_ EV kit, VCC = +4.75V to +5.25V, RBIAS = 5.9kΩ ±1%, inputs terminated to 75Ω, fRFIN = 50MHz to 878MHz, fIF =
45.75MHz (MAX3570/MAX3571), fIF = 38.9MHz (MAX3573), fCOMP1 = 1MHz, fCOMP2 = 62.5kHz, TA = 0°C to +70°C, unless otherwise noted. Typical values are at VCC = +5.0V, TA = +25°C, unless otherwise noted.) (Note 1)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
878
MHz
OVERALL REQUIREMENTS (RF INPUT TO 1st IF OUTPUT)
Operating Frequency Range
Gain specification met across this frequency band
Input Return Loss
Worst case across band, 75Ω, any RFVGA setting
ZSOURCE = 75Ω, ZLOAD = 200Ω,
VRFVGA = +3.0V
Voltage Gain
Gain-Reduction Range
IIP2
38.5
45.0
TA = +70°C
30.0
37
43.5
Measured at 50MHz
30
Beats within Output
+1.5
-2
+2
VRFVGA = +3.0V
7.9
VRFVGA = +3.0V, TA = +25°C to +70°C,
VCC = 4.85V to 5.15V, fRF = 860MHz
34
dB
dB
dBm
52.5
VRFVGA = +3.0V, TA = +25°C to +70°C,
VCC = 4.85V to 5.15V
+8
At 12dB gain reduction, TA = +25°C to +70°C,
VCC = 4.85V to 5.15V
+18
0dBmV PIX carrier level (Note 2)
-48
dBm
Channel Flatness
From PIX to (PIX + 4) MHz
-0.5
+0.3
Isolation
5MHz to 150MHz, RF input to IF output (Note 3)
-63
-68
Measured at 91MHz above desired PIX
(MAX3570/MAX3571)
50
55
dBc
+1.0
dB
dBc
dBc
Image Rejection
Measured at 77.75MHz above desired PIX
(MAX3573)
Spurious at RF Input (Note 3)
50MHz to 878MHz
Single Sideband Phase Noise
50
55
-54
Above 878MHz (LO and LO harmonics)
fOFFSET = 1kHz
Output Return Loss
dB
dB
-1.5
At 12dB gain reduction, TA = +25°C to +70°C,
VCC = 4.85V to 5.15V, fRF = 860MHz
IIP3
dB
31.5
VRFVGA = 0.5V at fRFIN = 878MHz vs. 50MHz
Noise Figure
8
TA = +25°C
VRFVGA = +3.0V at fRFIN = 878MHz vs. 50MHz
Gain Flatness
50
+3
dBmV
-62
fOFFSET = 10kHz, BWLOOP = 2.5kHz
-86
fOFFSET = 100kHz, BWLOOP = 2.5kHz
-105
Balanced, 50Ω
-48
9
dBc/Hz
dB
_______________________________________________________________________________________
3
MAX3570/MAX3571/MAX3573
AC ELECTRICAL CHARACTERISTICS
MAX3570/MAX3571/MAX3573
HI-IF Single-Chip Broadband Tuners
AC ELECTRICAL CHARACTERISTICS
(MAX357_ EV kit, VCC = +4.75V to +5.25V, RBIAS = 5.9kΩ ±1%, inputs terminated to 1kΩ, ZLOAD = 300Ω, fIF = 40MHz to 48MHz,
TA = 0°C to +70°C, unless otherwise noted. Typical values are at VCC = +5.0V, TA = +25°C, unless otherwise noted.) (Note 1)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
SECOND IF STAGE
Input Impedance
Balanced
Output Impedance
Balanced (Note 3)
Passband Voltage Gain
Passband Flatness
ZSOURCE = 1.1kΩ, ZLOAD = 300Ω, VIFVGA = +3.0V
1.7
kΩ
100
50
VIFVGA = +0.5V
53
57
14.5
23
From PIX to (PIX - 4) MHz for 45.75MHz PIX
frequency (Note 3)
Maximum Output Voltage
dB
0.2
dB
20
dB/V
180
MHz
3.2
VP-P
VGA Gain Slope
VIFVGA = +3.0V to +0.5V
-3dB Bandwidth
(Note 3)
Noise Figure
fIF = 44MHz, VIFVGA = +3.0V
5.1
dB
Noise Figure vs. Attenuation
First 10dB back-off
0.3
dB/dB
IIP3
10
Ω
Gain = 45dB, VOUT = 1.5VP-P
-27.5
Gain = 27dB, VOUT = 1.5VP-P
-11.3
dBm
OIP3
VOUT = 1.5VP-P, VIFVGA = +3.0V to +0.5V (Note 3)
25
dBm
PSRR
50mVP-P at 200kHz
-57
dB
4
_______________________________________________________________________________________
HI-IF Single-Chip Broadband Tuners
(MAX357_ EV kit, VCC = +4.75V to +5.25V, RBIAS = 5.9kΩ ±1%, fCOMP1 = 1MHz, fCOMP2 = 62.5kHz, TA = 0°C to +70°C, unless otherwise noted. Typical values are at VCC = +5.0V, TA = +25°C, unless otherwise noted.) (Note 1)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
1st LOCAL OSCILLATOR (LO1)
Tuning Range
1274
2111
MHz
40
120
MHz/V
RF1 N-Divider Ratio
256
8191
RF1 R-Divider Ratio
1
31
VCO Tuning Gain
1st LOCAL OSCILLATOR (LO1) DIVIDER
1st LOCAL OSCILLATOR (LO1) PHASE DETECTOR AND CHARGE PUMP
Phase-Detector Phase Noise
fOFFSET = 2kHz (Note 3)
Charge-Pump Source/Sink Matching
Correlate locked vs. unlocked
-142
dBc
6
%
Charge-Pump Tri-State Current
RF1
-7
+7
nA
1175
1193
MHz
25
70
MHz/V
RF2 N-Divider Ratio
512
65,535
RF2 R-Divider Ratio
2
127
2nd LOCAL OSCILLATOR (LO2)
Tuning Range
VCO Tuning Gain
2nd LOCAL OSCILLATOR (LO2) DIVIDER
2nd LOCAL OSCILLATOR (LO2) PHASE DETECTOR AND CHARGE PUMP
Phase-Detector Phase Noise
fOFFSET = 2kHz (Note 3)
Charge-Pump Source/Sink Matching
Correlate locked vs. unlocked
Charge-Pump Tri-State Current
RF2
-142
-7
dBc
6
%
+7
nA
LOGIC INTERFACE
(MAX357_ EV kit, VCC = +4.75V to +5.25V, RBIAS = 5.9kΩ ±1%, TA = 0°C to +70°C, unless otherwise noted.) (Note 1)
PARAMETER
Maximum Clock Frequency
CONDITIONS
MIN
400
TYP
MAX
UNITS
kHz
Note 1: These parameters are production tested from TA = +25°C to +70°C, and are guaranteed by design and characterization at
TA = 0°C.
Note 2: When using the tuning table provided in the EV kit documentation.
Note 3: These parameters are guaranteed by design and characterization, and are not production tested.
_______________________________________________________________________________________
5
MAX3570/MAX3571/MAX3573
SYNTHESIZER ELECTRICAL CHARACTERISTICS
Typical Operating Characteristics
(MAX357_ EV kit, VCC = +5.0V, RBIAS = 5.9kΩ, fRF = 860MHz, fIF = 44MHz (MAX3570/MAX3571), 36MHz (MAX3573), TA = +25°C,
unless otherwise noted.)
340
MAX3570/71/73 toc02
20
10
0
MAXIMUM GAIN
40
45
50
55
60
65
0.5
1.0
1.5
2.0
2.5
VOLTAGE GAIN
vs. FREQUENCY (MAX GAIN)
VOLTAGE GAIN
vs. FREQUENCY (MAX -12dB)
28
VOLTAGE GAIN (dB)
TA = +55°C
38
37
36
TA = +70°C
TA = +25°C
27
TA = +55°C
26
25
24
TA = +70°C
8.5
8.0
7.5
34
22
7.0
450
650
TA = +25°C
50
850
250
NOISE FIGURE vs. VOLTAGE GAIN
650
850
50
TA = +25°C
12
-60
-70
-80
-90
-100
-110
850
MAX3570/MAX3571
0
-10
MAX3573
-20
-120
-30
-130
10
650
IFOUT1 FREQUENCY RESPONSE
AMPLITUDE (dB)
TA = +55°C
450
10
MAX3570/71/73 toc08
TA = +70°C
-50
PHASE NOISE (dBc/Hz)
18
250
FREQUENCY (MHz)
PHASE NOISE vs. OFFSET FREQUENCY
MAX3570/71/73 toc07
20
14
450
FREQUENCY (MHz)
FREQUENCY (MHz)
16
TA = +55°C
TA = +70°C
9.0
23
250
5.05
9.5
35
50
4.95
10.0
NOISE FIGURE (dB)
40
4.85
NOISE FIGURE vs. FREQUENCY
29
MAX3570/71/73 toc04
41
4.75
3.0
SUPPLY VOLTAGE (V)
RFVGA VOLTAGE (V)
39
5.25
36
0
70
TEMPERATURE (°C)
TA = +25°C
5.15
850MHz
MAX3570/71/73 toc06
35
38
37
-20
30
450MHz
-10
300
25
50MHz
39
MAX3570/71/73 toc09
320
VOLTAGE GAIN (dB)
30
MAX3570/71/73 toc03
12dB ATTENTUATION
40
VOLTAGE GAIN (dB)
360
40
MAX3570/71/73 toc05
SUPPLY CURRENT (mA)
380
50
VOLTAGE GAIN (dB)
MAX3570/71/73 toc01
400
VOLTAGE GAIN
vs. SUPPLY VOLTAGE
VOLTAGE GAIN
vs. RFVGA VOLTAGE
SUPPLY CURRENT vs. TEMPERATURE
NOISE FIGURE (dB)
MAX3570/MAX3571/MAX3573
HI-IF Single-Chip Broadband Tuners
-140
8
29
31
33
35
VOLTAGE GAIN (dB)
6
37
39
-40
-150
100
1k
10k
100k
FREQUENCY (Hz)
1M
10M
0
50
100
IF FREQUENCY (MHz)
_______________________________________________________________________________________
150
HI-IF Single-Chip Broadband Tuners
TA = +25°C
50
TA = +70°C
45
40
23
-9.0
35
650
850
24
34
50
45
40
35
30
25
56
TA = +25°C
54
52
TA = +55°C
TA = +70°C
50
48
46
20
44
15
42
1.8
2.3
2.8
34
39
IFVGA NOISE FIGURE vs. IFVGA VOLTAGE
25
20
TA = +70°C
15
TA = +55°C
TA = +25°C
5
10
1
3.3
29
100
1000
IF FREQUENCY (MHz)
IFVGA VOLTAGE (V)
0.6 0.9 1.2 1.5 1.8 2.1 2.4 2.7 3.0 3.3
IFVGA VOLTAGE (V)
IFVGA INPUT IP3 vs. IFVGA VOLTAGE
-5
MAX3570/71/73 toc16
1.3
24
30
10
40
10
TA = +70°C
VOLTAGE GAIN (dB)
58
IFVGA VOLTAGE GAIN (dB)
MAX3570/71/73 toc13
55
TA = +25°C
19
39
IFVGA VOLTAGE GAIN vs. IF FREQUENCY
IFVGA VOLTAGE GAIN vs. IFVGA VOLTAGE
-10
INPUT IP3 (dBm)
IFVGA VOLTAGE GAIN (dB)
29
VOLTAGE GAIN (dB)
60
0.8
13
3
19
RF FREQUENCY (MHz)
0.3
18
MAX3570/71/73 toc15
450
NOISE FIGURE (dB)
250
MAX3570/71/73 toc14
50
TA = +55°C
8
TA = +55°C
30
-9.5
MAX3570/71/73 toc12
55
INPUT IP3 (dBm)
-8.5
28
MAX3570/71/73 toc11
MAX3570/71/73 toc10
60
INPUT IP2 (dBm)
RETURN LOSS (dB)
-8.0
INPUT IP3 vs. VOLTAGE GAIN
INPUT IP2 vs. VOLTAGE GAIN
RFIN INPUT RETURN LOSS
-7.5
TA = +70°C
-15
-20
TA = +55°C
-25
-30
TA = +25°C
-35
-40
0.3
0.8
1.3
1.8
2.3
2.8
3.3
IFVGA VOLTAGE (V)
_______________________________________________________________________________________
7
MAX3570/MAX3571/MAX3573
Typical Operating Characteristics (continued)
(MAX357_ EV kit, VCC = +5.0V, RBIAS = 5.9kΩ, fRF = 860MHz, fIF = 44MHz (MAX3570/MAX3571), 36MHz (MAX3573), TA = +25°C,
unless otherwise noted.)
MAX3570/MAX3571/MAX3573
HI-IF Single-Chip Broadband Tuners
Pin Description
PIN
NAME
1
VCC
RF Variable-Gain Amplifier (VGA) Supply Voltage. Bypass with a capacitor as close to the pin as possible.
Do not share the bypass capacitor ground vias with any other branches.
2, 3
RFIN+,
RFIN-
Differential LNA Inputs. Requires AC coupling and can be driven balanced or single-ended. Recommend
driving pin 3 and AC ground pin 2 for optimum input IP2 performance.
4, 6, 10,
20, 23,
24, 28,
32, 34, 45
GND
Ground. Connect to PC board ground plane.
5
VCC
1st Mixer Supply Voltage. Bypass with a capacitor as close to the pin as possible. Do not share the bypass
capacitor ground vias with any other branches.
7
VCC
1st VCO Circuitry Supply Voltage. Bypass with a capacitor as close to the pin as possible. Do not share the
bypass capacitor ground vias with any other branches.
8
TUNE1
9
LOCFLT1
11
12
FUNCTION
1st VCO Tuning Input. Connect this analog voltage input to a third-order loop-filter output.
1st LO Noise-Filtering Capacitor Connection. Connect a capacitor to GND. (Refer to the EV kit.)
I.C.
Internal Connection. Leave this pin unconnected (MAX3570).
ADDR2
2-Wire Serial Interface 2nd Address Pin (MAX3571/MAX3573)
CS
ADDR1
3-Wire Serial Interface Enable Input Pin (SPI™/QSPI™/MICROWIRE™ Compatible) (MAX3570)
2-Wire Serial Interface 1st Address Pin (MAX3571/MAX3573)
3-Wire Serial Interface Clock Input Pin (SPI/QSPI/MICROWIRE Compatible) (MAX3570)
13
SCL
14
SDA
15
VCC
16
DIV/LD
17
I.C.
18
CPOUT1
19
VCC
21
OSCOUT
22
OSCIN
Reference Oscillator Input. Connect an external reference oscillator or crystal to this analog input through a
coupling capacitor.
25
VCC
2nd Synthesizer Supply Voltage. Bypass with a capacitor as close to the pin as possible. Do not share the
bypass capacitor ground vias with any other branches.
26
CPOUT2
2-Wire Serial Interface Clock Input Pin (MAX3571/MAX3573)
3-Wire Serial Interface Data Input Pin (SPI/QSPI/MICROWIRE Compatible) (MAX3570)
2-Wire Serial Interface Data Input Pin (MAX3571/MAX3573)
Digital Circuitry Supply Voltage. Bypass with a capacitor as close to the pin as possible. Do not share the
bypass capacitor ground vias with any other branches.
Divider or Lock-Detect Logic Output
Internal Connection. Leave this pin unconnected.
1st PLL Charge-Pump Output. Connect this high-impedance current output to a third-order loop-filter input.
1st Synthesizer Supply Voltage. Bypass with a capacitor as close to the pin as possible. Do not share the
bypass capacitor ground vias with any other branches.
Reference Oscillator Buffered Output
2nd PLL Charge-Pump Output. Connect this high-impedance current output to a third-order loop-filter input.
SPI and QSPI are trademarks of Motorola, Inc.
MICROWIRE is a trademark of National Semiconductor Corp.
8
_______________________________________________________________________________________
HI-IF Single-Chip Broadband Tuners
PIN
NAME
27
VCC
29
LOCFLT2
30
TUNE2
31
VCC
2nd VCO Circuitry Supply Voltage. Bypass with a capacitor as close to the pin as possible. Do not share
the bypass capacitor ground vias with any other branches.
33
VCC
2nd LO Generation Supply Voltage. Bypass with a capacitor as close to the pin as possible. Do not share
the bypass capacitor ground vias with any other branches.
35, 36
FUNCTION
2nd Charge-Pump Supply Voltage. Bypass with a capacitor as close to the pin as possible. Do not share
the bypass capacitor ground vias with any other branches.
2nd LO Noise-Filtering Capacitor Connector. Connect a capacitor to GND. (Refer to the EV kit.)
2nd VCO Tuning Input. Connect this analog voltage input to a third-order loop-filter output.
IFOUT1+,
1st Differential IF Outputs. These outputs are AC-coupled to the SAW filter inputs.
IFOUT12nd Mixer and 1st IF Amplifier Circuit Supply Voltage. Bypass with a capacitor as close to the pin as
possible. Do not share the bypass capacitor ground vias with any other branches.
37
VCC
38, 39
IFIN+,
IFIN-
Differential IF Inputs. Connected to the SAW filter outputs.
40
IFVGA
IF VGA Control. See the Typical Operating Characteristics.
41
VCC
42, 43
IF VGA Supply Voltage. Bypass with a capacitor as close to the pin as possible. Do not share the bypass
capacitor ground vias with any other branches.
IFOUT2+,
IF VGA Outputs
IFOUT2-
44
VCC
HI-IF Filter Circuit Supply Voltage. Bypass with a capacitor as close to the pin as possible. Do not share the
bypass capacitor ground vias with any other branches.
46
BIAS
Bias Resistor Connection. Connect a 5.9kΩ precision ±1% resistor to GND. Resistor value can be increased
to decrease the nominal current at the expense of linearity. Refer to Application Note:
MAX3570/MAX3571/MAX3573 Bias Resistor Setting for further information.
47
RFVGA
48
LNABIAS
EP
GND
RF VGA Control. See the Typical Operating Characteristics.
LNA Bias Input. Connect through an inductor to GND. (Refer to the EV kit.)
Exposed Ground Paddle. DC and AC GND return for the IC. Connect to PC board ground plane using
multiple vias.
_______________________________________________________________________________________
9
MAX3570/MAX3571/MAX3573
Pin Description (continued)
MAX3570/MAX3571/MAX3573
HI-IF Single-Chip Broadband Tuners
Detailed Description
Programmable Registers
The MAX3570/MAX3571/MAX3573 include nine programmable registers (registers 1–9) consisting of six
divider registers (registers 1–6), one VCO control register
(register 7), and one test register (register 8). The final
register (register 9) controls the HI-IF filter frequency offset, as well as the DIV/LD output MUX status. Most registers contain some don’t care (X) bits. These can be
either a “0” or a “1” and do not affect the mode of operation (Table 1). Data is shifted in MSB first. Positive logic
is used.
3-Wire Serial Interface
The MAX3570 uses a 3-wire SPI/QSPI/MICROWIREcompatible serial interface. An active-low chip select
(CS) enables the device to receive data from the serial
input (SDA). Register address and data information are
clocked in on the rising edge of the serial clock signal
(SCL). While shifting in the serial data, the device
remains in its original configuration. A rising edge on
CS latches the data into the MAX3570’s internal register, initiating the device’s change of state. Figure 1
shows the details of the 3-wire interface address and
data configuration.
2-Wire Serial Interface
The MAX3571/MAX3573 use a 2-wire I2C*-compatible
serial interface. The serial bus is monitored continuously, waiting for a START condition followed by its
address. The address has 5 MSB internally set, while
the next two bits are set with external pins, ADDR2 and
ADDR1. The LSB determines whether it is a read or
write. When the device recognizes its address, it
acknowledges by pulling the SDA line low for one clock
period; it is then ready to accept the register address
for the first byte of data. Another acknowledge (ACK) is
sent once the register address is received. The device
is then ready to accept the data byte. More data bytes
can be sent for sequential registers, and ACK is sent
after each byte. After the final ACK is sent, the master
issues a STOP condition to free the bus. Figure 2 shows
the details of the 2-wire interface structure.
There is only one read-back register in the
MAX3571/MAX3573. To access it, send a START condition, and then the read address is set by the external
ADDR2 and ADDR1 pins. An ACK is sent, and the master then begins to read from the slave. After the eight
bits have been read, the master should issue a noacknowledge (NACK), and then a STOP condition.
Figure 1. 3-Wire Serial Interface Address and Data Configuration
MSB
LSB
4 ADDRESS BITS
A3
A2
A1
8 DATA BITS
A0
D7
D6
D5
D4
D3
D2
D1
D0
Figure 2. 2-Wire Serial Interface Register Write Example
START
DEVICE ADDRESS
8b11000<ADDR2><ADDR1>0
ACK
REGISTER ADDRESS
8b0000XXXX
ACK
DATA
D7–D0
ACK
DATA
D7–D0
ACK
STOP
Figure 3. 2-Wire Serial Interface Register Read Example
START
DEVICE ADDRESS
8b11000<ADDR2><ADDR1>1
ACK
READ BYTE (8 Bits)
8bXXXXXXXX
NACK
STOP
Table 1. 2-Wire Serial Interface Address
Configuration (Set by ADDR2 and
ADDR1)
*Purchase of I2C components of Maxim Integrated Products,
Inc., or one of its sublicensed Associated Companies, conveys
a license under the Philips I2C Patent Rights to use these components in an I2C system, provided that the system conforms
to the I2C Standard Specification as defined by Philips.
10
ADDRESS (WRITE/READ)
ADDR2
ADDR1
C0/C1hex
Low
Low
C2/C3hex
Low
High
C4/C5hex
High
Low
C6/C7hex
High
High
______________________________________________________________________________________
HI-IF Single-Chip Broadband Tuners
MSB
REGISTER
NUMBER
REGISTER
NAME
LSB
REGISTER
ADDRESS
8 DATA BITS
D7
D6
D5
D4
D3
D2
DB1
D0
1
VCO1_N1
00hex
X
X
X
1N12
1N11
1N10
1N9
1N8
2
VCO1_N2
01hex
1N7
1N6
1N5
1N4
1N3
1N2
1N1
1N0
3
VCO1_R
02hex
X
X
X
1R4
1R3
1R2
1R1
1R0
4
VCO2_N1
03hex
2N15
2N14
2N13
2N12
2N11
2N10
2N9
2N8
5
VCO2_N2
04hex
2N7
2N6
2N5
2N4
2N3
2N2
2N1
2N0
6
VCO2_R
05hex
X
2R6
2R5
2R4
2R3
2R2
2R1
2R0
7
VCO_SET
06hex
1VCO2
1VCO1
1VCO0
X
1CP1
1CP0
2CP1
2CP0
8
TEST
07hex
X
1T4
1T3
1T2
1T1
1T0
ST1
ST0
9
HI-IF
08hex
X
X
F1
F0
MUX3
MUX2
MUX1
MUX0
X = Don’t care.
Table 3. Register Description
REGISTER
NUMBER
REGISTER
NAME
REGISTER
ADDRESS
1
VCO1_N1
00hex
VCO1 N-divider high
2
VCO1_N2
01hex
VCO1 N-divider low
3
VCO1_R
02hex
VCO1 R-divider
4
VCO2_N1
03hex
VCO2 N-divider high
5
VCO2_N2
04hex
VCO2 N-divider low
6
VCO2_R
05hex
VCO2 R-divider
7
VCO_SET
06hex
VCO select and charge-pump settings
8
TEST
07hex
Test mode. For test purposes only. Program to 20hex.
9
HI-IF
08hex
Mode select, MUX output select
FUNCTION
Table 4. 1st VCO N-Divider Higher Register (VCO1_N1)
BIT ID
BIT NAME
BIT LOCATION (0 = LSB)
X
X
7, 6, 5
1N
1st VCO N-Divider
4–0
FUNCTION
Reserved
1st VCO N-divider MSB bits
Table 5. 1st VCO N-Divider Lower Register (VCO1_N2)
BIT ID
BIT NAME
BIT LOCATION (0 = LSB)
1N
1st VCO N-Divider
7–0
FUNCTION
1st VCO N-divider LSB bits
______________________________________________________________________________________
11
MAX3570/MAX3571/MAX3573
Table 2. Register Configuration
MAX3570/MAX3571/MAX3573
HI-IF Single-Chip Broadband Tuners
Table 6. 1st VCO R-Divider Higher Register (VCO1_R)
BIT ID
BIT NAME
BIT LOCATION (0 = LSB)
X
X
7, 6, 5
1R
1st VCO R-Divider
4–0
FUNCTION
Reserved
1st VCO R-divider
Table 7. 2nd VCO N-Divider Higher Register (VCO2_N1)
BIT ID
BIT NAME
BIT LOCATION (0 = LSB)
2N
2nd VCO N-Divider
7–0
FUNCTION
2nd VCO N-divider MSB bits
Table 8. 2nd VCO N-Divider Lower Register (VCO2_N2)
BIT ID
BIT NAME
BIT LOCATION (0 = LSB)
2N
2nd VCO N-Divider
7–0
FUNCTION
2nd VCO N-divider LSB bits
Table 9. 2nd VCO R-Divider Higher Register (VCO2_R)
BIT ID
BIT NAME
BIT LOCATION (0 = LSB)
X
X
7
2R
2nd VCO R-Divider
6–0
FUNCTION
Reserved
2nd VCO R-divider
Table 10. VCO Tank and Charge-Pump Select Register (VCO_SET)
BIT ID
BIT LOCATION (0 = LSB)
1VCO
1st VCO Tank Select
7, 6, 5
X
X
4
1CP
2CP
12
BIT NAME
1st VCO Charge-Pump
Current
2nd VCO Charge-Pump
Current
FUNCTION
1st VCO Tank Select:
• 000 = 1st VCO tank (the lowest frequency oscillator)
• 001 = 2nd VCO tank
• 010 = 3rd VCO tank
• 011 = 4th VCO tank
• 100 = 5th VCO tank
• 101 = 6th VCO tank
• 110 = 7th VCO tank
• 111 = 8th VCO tank (the highest frequency oscillator)
Reserved
3, 2
1st VCO Charge-Pump Current:
• 00 = 0.2mA
• 01 = 0.4mA
• 10 = 0.6mA
• 11 = 0.8mA
1, 0
2nd VCO Charge-Pump Current:
• 00 = 0.2mA
• 01 = 0.4mA
• 10 = 0.6mA
• 11 = 0.8mA
______________________________________________________________________________________
HI-IF Single-Chip Broadband Tuners
BIT ID
BIT NAME
BIT LOCATION (0 = LSB)
X
X
7, 6
Reserved
5, 4
HI-IF Filter Control:
• 00 = Step down 5MHz
• 01 = Nominal
• 11 = Step up 5MHz
3–0
Lock-Detect and MUX Output Control:
• 0000 = Normal, low-noise operation
• 0001 = Lock detect for the 1st VCO
• 0010 = Lock detect for the 2nd VCO
• 0011 = 1st VCO N-divider
• 0100 = 1st VCO R-divider
• 0101 = 2nd VCO N-divider
• 0110 = 2nd VCO R-divider
• 0111 = Reference oscillator
• 1000 = AND output of lock detector
• 1001 = NAND output of lock detector
• 1010 = 1st VCO VTUNE over/under indicator
• 1011 = 2nd VCO VTUNE over/under indicator
F
HI-IF Filter Control
Lock-Detect and MUX
Output Control
MUX
FUNCTION
Table 12. Read Mode Register Configuration
MSB
REGISTER
NUMBER
REGISTER
NAME
1
LD_POR
LSB
8 DATA BITS
D7
D6
D5
D4
D3
D2
DB1
D0
LOCK1
LOCK2
POR
OU1
OU2
X
X
X
Table 13. Read Mode Register Description
REGISTER NUMBER
REGISTER NAME
1
LD_POR
FUNCTION
Lock detect and power-on reset
Table 14. Lock Detect and POR Register
BIT ID
BIT NAME
BIT LOCATION
(0 = LSB)
LOCK1
LOCK1
7
Lock indicator for 1st VCO (see Table 15)
LOCK2
LOCK2
6
Lock indicator for 2nd VCO
FUNCTION
POR
POR
5
Power-on reset indicator; 1 indicates successful power-on reset
OU1
OU1
4
Over or Under VTUNE indicator for 1st VCO (see Table 15)
OU2
OU2
3
Over or Under VTUNE indicator for 2nd VCO
X
X
2, 1, 0
Reserved
Table 15. 1st VCO Truth Table
LOCK1
OU1
1
x
1st VCO locked
DESCRIPTION
0
0
(Under) Choose next lower tank
0
1
(Over) Choose next higher tank
______________________________________________________________________________________
13
MAX3570/MAX3571/MAX3573
Table 11. HI-IF Step Control and MUX Output Register (HI-IF)
Typical Application Circuit
IF OUTPUT
TO ADC
FROM DAC
48
VCC
IFIN+
IFIN-
IFVGA
VCC
IFOUT2+
IFOUT2-
VCC
GND
BIAS
36
IFOUT1-
1
2
35
MAX3570
3
34
HI-IF
FILTER
4
33
5
32
6
31
7
30
8
29
9
28
10
I.C. 11
CS
37
27
DUAL SYNTHESIZER
26
3-WIRE SERIAL
INTERFACE
12
25
13
14
15
16
17
18
19
20
21
22
23
IFOUT1+
GND
VCC
GND
VCC
TUNE2
LOCFLT2
GND
VCC
CPOUT2
VCC
24
GND
GND
38
GND
LOCFLT1
39
OSCIN
TUNE1
40
OSCOUT
VCC
41
GND
GND
42
VCC
VCC
43
CPOUT1
GND
44
I.C.
RFIN-
45
DIV/LD
RF
INPUT
46
VCC
RFIN+
47
SDA
VCC
RFVGA
LNABIAS
FROM DAC
SCL
MAX3570/MAX3571/MAX3573
HI-IF Single-Chip Broadband Tuners
SERIAL INTERFACE
14
______________________________________________________________________________________
HI-IF Single-Chip Broadband Tuners
RF Input
An LNA provides a single-ended broadband input
matched to a 75Ω source. It provides a linear, continuous gain-control range of over 30dB before the signal is
upconverted. A 16nH inductor in series with a 1000pF
capacitor is required at the RF input (pin 3) to achieve
optimal matching (see the Typical Application Circuit).
HI-IF Frequency Agility
In a double conversion receiver, beat frequencies are
generated from harmonics of the LOs associated with
this system. In some instances these beat frequencies
may coincide with the IF. If this occurs, it is possible to
shift the HI-IF slightly by retuning the LOs. This shift
moves the beat out of the IF band. The MAX3570/
MAX3571/MAX3573 support this capability by allowing
the user to shift the center frequency of the HI-IF filter
slightly, tracking the shift in the LO frequencies, preserving the optimum image rejection and insertion loss.
The HI-IF filter frequency shift is controlled with the HIIF filter step control bits (F0 and F1, register address 8).
(Patent pending.)
IF Outputs
A first differential IF output (IFOUT1+, IFOUT1-),
although intended to drive a standard IF SAW filter, is
capable of driving loads as low as 200Ω. A second differential IF output (IFOUT2+, IFOUT2-) provides a balanced output capable of driving loads as low as 300Ω
and can be AC-coupled to a standard QAM demodulator’s ADC.
Gain Control
The MAX3570/MAX3571/MAX3573 have two VGA circuits that are used to achieve the optimum SNR while
minimizing distortion. At low input signal levels the
RFVGA voltage should be 3.0V. This sets the LNA gain
at its maximum. The IFVGA control voltage is used to set
the required output signal level. As the RF input level
increases, the IFVGA voltage drops. When the IFVGA
voltage reaches a user-defined value (RFVGA attack
point), the IFVGA voltage is frozen and the RFVGA voltage is adjusted to maintain the desired output level.
VCO1 Selection
Synthesizer Comparison
Frequency Selection
The two on-chip synthesizers of the MAX3570/MAX3571/
MAX3573 are capable of supporting a wide range of
comparison frequencies. The PLL for the first LO (LO1)
provides a comparison frequency range from below
250kHz up to 4MHz, assuming a 4MHz reference (crystal) frequency. The second LO (LO2) PLL supports a
comparison frequency range from below 50kHz up to
2MHz, again assuming a 4MHz reference.
Comparison frequencies of 1MHz for LO1 (R1 = 4) and
250kHz for LO2 (R2 = 16) are recommended for the
MAX3570 and MAX3571. For the MAX3573, the recommended LO2 comparison frequency is 142.8571kHz (R2
= 28, 4MHz crystal frequency). These values ensure optimum resolution while working with the loop filters to suppress spurious energy and provide acceptable lock time.
Synthesizer Loop Filters
A third-order lowpass loop filter is used for each local
oscillator to achieve low spurious and low phase noise.
The loop bandwidth is chosen so the spurious rejection
is sufficient and a reasonable lock time is achieved.
Refer to the EV kit for the recommended loop-filter component values.
Crystal Oscillator Interface
The crystal oscillator pins (OSCIN, OSCOUT) must be
connected to a crystal or an external reference oscillator. When connecting directly to a crystal, refer to the EV
kit for the recommended component values. When
using an external reference oscillator, drive OSCIN with
an amplitude of 1.5VP-P, and leave OSCOUT unconnected.
Power-Supply Layout
To minimize coupling between different sections of the IC,
the ideal power-supply layout is a star configuration, which
has a large decoupling capacitor at a central VCC node.
The VCC traces branch out from this node, each going to
a separate V CC node in the MAX3570/MAX3571/
MAX3573 circuit. At the end of each trace is a bypass
capacitor with a low impedance to ground at the frequency of interest. This arrangement provides local decoupling
at each VCC pin. Use at least one via per bypass capacitor for a low-inductance ground connection.
VCO1 generates the first local oscillator (LO1) frequency for the upconverting mixer. It consists of an array of
eight VCOs; each tuned to a unique frequency band, to
cover the required frequency range. The desired VCO
is chosen through the serial data interface (SDI). Please
refer to Application Note: MAX3550/MAX3551/
MAX3553 VCO Selection for further information on
VCO1 VCO selection.
______________________________________________________________________________________
15
MAX3570/MAX3571/MAX3573
Applications Information
RFVGA
GND
VCC
IFOUT2-
IFOUT2+
VCC
IFVGA
IFIN-
IFIN+
VCC
48
BIAS
LNABIAS
Pin Configurations/
Functional Diagrams (continued)
47
46
45
44
43
42
41
40
39
38
37
VCC 1
36 IFOUT1-
RFIN+ 2
35 IFOUT1+
MAX3571
MAX3573
RFIN- 3
33 VCC
VCC 5
32 GND
GND 6
31 VCC
VCC 7
30 TUNE2
TUNE1 8
29 LOCFLT2
LOCFLT1 9
28 GND
GND 10
ADDR2 11
27 VCC
DUAL SYNTHESIZER
Chip Information
TRANSISTOR COUNT: 18,970
PROCESS: SiGe BiCMOS
26 CPOUT2
2-WIRE SERIAL
INTERFACE
14
15
16
17
18
19
20
21
22
23
24
VCC
DIV/LD
I.C.
CPOUT1
VCC
GND
OSCOUT
OSCIN
GND
GND
25 VCC
13
SCL
ADDR1 12
16
Matching Network Layout
The layout of a matching network can be very sensitive
to parasitic circuit elements. To minimize parasitic
inductance, keep all traces short and place components as close to the IC as possible. To minimize parasitic capacitance, a cutout in the ground plane (and
any other planes) below the matching network components can be used. Refer to the EV kit for the recommended input matching network.
34 GND
HI-IF
FILTER
GND 4
SDA
MAX3570/MAX3571/MAX3573
HI-IF Single-Chip Broadband Tuners
______________________________________________________________________________________
HI-IF Single-Chip Broadband Tuners
32, 44, 48L QFN.EPS
PACKAGE OUTLINE
32,44,48L QFN, 7x7x0.90 MM
21-0092
H
1
2
U
PACKAGE OUTLINE,
32,44,48L QFN, 7x7x0.90 MM
21-0092
H
2
2
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 17
© 2005 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products, Inc.
MAX3570/MAX3571/MAX3573
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,
go to www.maxim-ic.com/packages.) Refer to G4877-1.