19-0068; Rev 5; 10/09
KIT
ATION
EVALU
LE
B
A
IL
A
AV
ISDB-T Single-Segment Low-IF Tuners
Features
The MAX2160/EBG tuner ICs are designed for use in
Japanese mobile digital TV (ISDB-T single-segment)
applications. The devices directly convert UHF band
signals to a low-IF using a broadband I/Q downconverter. The operating frequency range extends from
470MHz to 770MHz.
The MAX2160/EBG support both I/Q low-IF interfaces
as well as single low-IF interfaces, making the devices
universal tuners for various digital demodulator IC
implementations.
♦ Low Noise Figure: < 4dB Typical
♦ High Dynamic Range: -98dBm to 0dBm
♦ High-Side or Low-Side LO Injection
♦
♦
♦
♦
♦
Integrated VCO and Tank Circuits
Low LO Phase Noise: Typical -88dBc/Hz at 10kHz
Integrated Frequency Synthesizer
Integrated Bandpass Filters
52dB Typical Image Rejection
The MAX2160/EBG include an LNA, RF variable-gain
amplifiers, I and Q downconverting mixers, low-IF variablegain amplifiers, and bandpass filters providing in excess of
42dB of image rejection. The parts are capable of operating with either high-side or low-side local oscillator (LO)
injection. The MAX2160/EBG’s variable-gain amplifiers provide in excess of 100dB of gain-control range.
The MAX2160/EBG also include fully monolithic VCOs
and tank circuits, as well as a complete frequency synthesizer. The devices include a XTAL oscillator as well
as a separate TCXO input buffer. The devices operate
with XTAL/TCXO oscillators from 13MHz to 26MHz
allowing the shared use of a VC-TCXO in cellular handset applications. Additionally, a divider is provided for
the XTAL/TCXO oscillator allowing for simple and lowcost interfacing to various channel decoders.
The MAX2160/EBG are specified for operation from
-40°C to +85°C and available in a 40-pin (6mm x 6mm)
thin QFN lead-free plastic package with exposed paddle (EP), and in a 3.175mm x 3.175mm lead-free waferlevel package (WLP).
♦
♦
♦
♦
Single +2.7V to +3.3V Supply Voltage
Three Low-Power Modes
Two-Wire, I2C-Compatible Serial Control Interface
Very Small Lead-Free WLP Package
TEMP RANGE
-40°C to +85°C
40 Thin QFN-EP*
MAX2160ETL+
-40°C to +85°C
40 Thin QFN-EP*
MAX2160EBG+
-40°C to +85°C
WLP
VCCCP
CPOUT
TEST
GNDTUNE
VTUNE
GNDVCO
VCCVCO
VCOBYP
N.C.
GNDCP
37
36
35
34
33
32
31
30 N.C.
TANK
29 VCCBB
28 N.C.
DIV4
27 QOUT
GNDXTAL 4
÷
VCCXTAL 5
26 GNDBB
25 IOUT
XTALOUT 6
INTERFACE LOGIC
AND CONTROL
24 N.C.
MAX2160
23 GC2
PWRDET
EP
22 ENTCXO
16
17
18
19
20
VCCMX
PWRDET
VCCFLT
SHDN
15
GC1
14
N.C.
13
VCCLNA
12
RFIN
21 N.C.
11
N.C.
VCCDIG 7
LTC 10
MAX2160ETL
38
XTAL 3
SCL 9
PIN-PACKAGE
39
FREQUENCY
SYNTHESIZER
TCXO 2
SDA 8
Ordering Information
PART
40
N.C. 1
VCCBIAS
Cell Phone Mobile TVs
Personal Digital Assistants (PDAs)
Pocket TVs
TOP VIEW
ADC
Applications
Pin Configurations/
Functional Diagrams
TQFN
Pin Configurations/Functional Diagrams continued at end of
data sheet.
+Denotes a lead(Pb)-free/RoHS-compliant package.
*EP = Exposed paddle.
________________________________________________________________ Maxim Integrated Products
1
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
MAX2160/MAX2160EBG
General Description
MAX2160/MAX2160EBG
ISDB-T Single-Segment Low-IF Tuners
ABSOLUTE MAXIMUM RATINGS
All VCC_ Pins to GND............................................-0.3V to +3.6V
All Other Pins to GND.................................-0.3V to (VCC + 0.3V)
RFIN, Maximum RF Input Power ....................................+10dBm
ESD Rating...........................................................................±1kV
Short-Circuit Duration
IOUT, QOUT, CPOUT, XTALOUT, PWRDET, SDA,
TEST, LTC, VCOBYP ...........................................................10s
Continuous Power Dissipation (TA = +70°C)
40-Pin Thin QFN (derate 35.7mW/°C above +70°C)....2857mW
WLP (derate 10.8mW/°C above +70°C).........................704mW
Operating Temperature Range ...........................-40°C to +85°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
(MAX2160 EV kit, VCC = +2.7V to +3.3V, VGC1 = VGC2 = 0.3V (maximum gain), no RF input signals at RFIN, baseband I/Os are open
circuited and VCO is active with fLO = 767.714MHz, registers set according to the recommended default register conditions of
Tables 2–11, TA = -40°C to +85°C, unless otherwise noted. Typical values are at VCC = +2.85V, TA = +25°C, unless otherwise
noted.) (Note 1)
PARAMETER
CONDITIONS
MIN
TYP
2.7
MAX
UNITS
V
SUPPLY
Supply Voltage
Supply Current (See Tables 15
and 16)
2.85
3.3
Receive mode, SHDN = VCC , BBL[1:0] = 00
44
53.5
Standby mode, bit STBY = 1
2
4
Power-down mode, bit PWDN = 1, EPD = 0
5
40
Shutdown mode, SHDN = GND
0
10
mA
µA
ANALOG GAIN-CONTROL INPUTS (GC1, GC2)
Input Voltage Range
Maximum gain = 0.3V
Input Bias Current
0.3
2.7
V
-15
+15
µA
0.4
2.3
V
VCO TUNING VOLTAGE INPUT (VTUNE)
Input Voltage Range
VTUNE ADC
Resolution
3
Input Voltage Range
Reference Ladder Trip Point
0.3
ADC read bits
bits
2.4
110 to 111
VCC - 0.4
101 to 110
1.9
100 to 101
1.7
011 to 100
1.3
010 to 011
0.9
001 to 010
0.6
000 to 001
0.4
V
V
LOCK TIME CONSTANT OUTPUT (LTC)
Source Current
2
Bit LTC = 0
1
Bit LTC = 1
2
_______________________________________________________________________________________
µA
ISDB-T Single-Segment Low-IF Tuners
(MAX2160 EV kit, VCC = +2.7V to +3.3V, VGC1 = VGC2 = 0.3V (maximum gain), no RF input signals at RFIN, baseband I/Os are open
circuited and VCO is active with fLO = 767.714MHz, registers set according to the recommended default register conditions of
Tables 2–11, TA = -40°C to +85°C, unless otherwise noted. Typical values are at VCC = +2.85V, TA = +25°C, unless otherwise
noted.) (Note 1)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
SHUTDOWN CONTROL (SHDN)
Input-Logic-Level High
0.7 x VCC
V
Input-Logic-Level Low
0.3 x VCC
V
2-WIRE SERIAL INPUTS (SCL, SDA)
Clock Frequency
400
Input-Logic-Level High
0.7 x VCC
V
Input-Logic-Level Low
Input Leakage Current
0.3 x VCC
Digital inputs = GND or VCC
kHz
±0.1
±1
V
µA
2-WIRE SERIAL OUTPUT (SDA)
Output-Logic-Level Low
0.2
V
AC ELECTRICAL CHARACTERISTICS
(MAX2160 EV kit, VCC = +2.7V to +3.3V, fRF = 767.143MHz, fLO = 767.714MHz, fBB = 571kHz, fXTAL = 16MHz, VGC1 = VGC2 = 0.3V
(maximum gain), registers set according to the recommended default register conditions of Tables 2–11, RF input signals as specified, baseband output load as specified, TA = -40°C to +85°C, unless otherwise noted. Typical values are at VCC = +2.85V,
TA = +25°C, unless otherwise noted.) (Note 1)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
770
MHz
MAIN SIGNAL PATH PERFORMANCE
Input Frequency Range
470
Minimum Input Signal
13-segment input
Maximum Voltage Gain
CW tone, VGC1 = VGC2 = 0.3V, bit MOD = 1
Minimum Voltage Gain
CW tone, VGC1 = VGC2 = 2.7V, bit MOD = 0
RF Gain-Control Range
0.3V < VGC1 < 2.7V
38
43
Baseband Gain-Control Range
0.3V < VGC2 < 2.7V
57
67
dB
In-Band Input IP3
(Note 2)
+4
dBm
Out-of-Band Input IP3
(Note 3)
+16.7
dBm
Input IP2
(Note 4)
+16
dBm
Input P1dB
CW tone, VGC1 = VGC2 = 2.7V, bit MOD = 0
0
dBm
Noise Figure
VGC1 = VGC2 = 0.3V, TA = +25°C (Note 5)
Image Rejection
-98
dB
4
3.8
42
Minimum RF Input Return Loss
dBm
102
fRF = 620MHz, 50Ω system
LO Leakage at RFIN
dB
dB
5
dB
52
dB
14
dB
-100
dBm
3
bits
IF POWER DETECTOR
Resolution
Minimum RF Attack Point
Power at RFIN
-62
dBm
Maximum RF Attack Point
Power at RFIN
-48
dBm
Detector Bandwidth
3dB RF bandwidth
Output Compliance Range
Response Time
±35
0.3
C14 = 10nF
MHz
2.7
0.1
V
ms
_______________________________________________________________________________________
3
MAX2160/MAX2160EBG
DC ELECTRICAL CHARACTERISTICS (continued)
MAX2160/MAX2160EBG
ISDB-T Single-Segment Low-IF Tuners
AC ELECTRICAL CHARACTERISTICS (continued)
(MAX2160 EV kit, VCC = +2.7V to +3.3V, fRF = 767.143MHz, fLO = 767.714MHz, fBB = 571kHz, fXTAL = 16MHz, VGC1 = VGC2 = 0.3V
(maximum gain), registers set according to the recommended default register conditions of Tables 2–11, RF input signals as specified, baseband output load as specified, TA = -40°C to +85°C, unless otherwise noted. Typical values are at VCC = +2.85V,
TA = +25°C, unless otherwise noted.) (Note 1)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
LOW-IF BANDPASS FILTERS
Center Frequency
Frequency Response (Note 5)
Group Delay Variation
571
±380kHz offset from center frequency
-6
1.3MHz
kHz
-1.5
-36
Up to 1dB bandwidth
±100
dB
ns
BASEBAND OUTPUT CHARACTERISTICS
Nominal Output-Voltage Swing
RLOAD = 10kΩ || 10pF
I/Q Amplitude Imbalance
(Note 6)
0.5
I/Q Quadrature Phase Imbalance
VP-P
±1.5
dB
±2
deg
Output Gain Step
Bit MOD transition from 0 to 1
+7
dB
I/Q Output Impedance
Real ZO
30
Ω
FREQUENCY SYNTHESIZER
RF-Divider Frequency Range
470
770
RF-Divider Range (N)
829
5374
Reference-Divider Frequency
Range
13
26
Reference-Divider Range (R)
22
182
Phase-Detector Comparison
Frequency
1/7
4/7
MHz
MHz
MHz
PLL-Referred Phase Noise Floor
TA = +25°C, fCOMP = 285.714kHz
-155
dBc/Hz
Comparison Frequency Spurious
Products
Bit EPB = 1
-52
dBc
Bits CP[1:0] = 00
1.25
1.5
1.75
Bits CP[1:0] = 01
1.65
2.0
2.35
Bits CP[1:0] = 10
2.10
2.5
2.90
Bits CP[1:0] = 11
2.50
3
3.50
Charge-Pump Compliance
Range
±10% variation from current at VTUNE = 1.35V
0.4
2.2
V
Charge-Pump Source/Sink
Current Matching
VTUNE = 1.35V
-10
+10
%
Charge-Pump Output Current
(Note 5)
4
_______________________________________________________________________________________
mA
ISDB-T Single-Segment Low-IF Tuners
(MAX2160 EV kit, VCC = +2.7V to +3.3V, fRF = 767.143MHz, fLO = 767.714MHz, fBB = 571kHz, fXTAL = 16MHz, VGC1 = VGC2 = 0.3V
(maximum gain), registers set according to the recommended default register conditions of Tables 2–11, RF input signals as specified, baseband output load as specified, TA = -40°C to +85°C, unless otherwise noted. Typical values are at VCC = +2.85V,
TA = +25°C, unless otherwise noted.) (Note 1)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
VOLTAGE-CONTROLLED OSCILLATOR AND LO GENERATION
Guaranteed VCO Frequency
Range
TA = -40°C to +85°C
1880
3080
MHz
Guaranteed LO Frequency
Range
TA = -40°C to +85°C
470
770
MHz
2.3
V
Tuning Voltage Range
0.4
0.4V < VTUNE < 2.3V,
TA = -40°C to +85°C
LO Phase Noise
fOFFSET = 1kHz
-80
fOFFSET = 10kHz
-87.5
fOFFSET = 100kHz
-107
fOFFSET = 1MHz
-128
dBc/Hz
XTAL OSCILLATOR INPUT (TCXO AND XTAL)
XTAL Oscillator Frequency
Range
Parallel resonance mode crystal
XTAL Minimum Negative
Resistance
16MHz < fXTAL < 18MHz (Note 5)
13
13.3
AC-coupled sine-wave input
0.4
TCXO Minimum Input Impedance
MHz
Ω
885
XTAL Nominal Input Capacitance
TCXO Input Level
26
pF
1.5
10
VP-P
kΩ
REFERENCE OSCILLATOR BUFFER OUTPUT (XTALOUT)
Output Frequency Range
1
Output-Buffer Divider Range
1
Output-Voltage Swing
26
MHz
26
0.7
VP-P
200 || 4
kΩ || pF
Output Duty Cycle
50
%
Output Impedance
160
Ω
Output Load
Note 1: Min and max values are production tested at TA = +25°C and +85°C. Min and max limits at TA = -40°C are guaranteed by
design and characterization. Default register settings are not production tested; load all registers no sooner than 100µs
after power-up.
Note 2: In-band IIP3 is measured with two tones at fLO - 100kHz and fLO - 200kHz at a power level of -23dBm/tone. GC1 is set for
maximum attenuation (VGC1 = 2.7V) and GC2 is adjusted to achieve 250mVP-P/tone at the I/Q outputs for an input desired
level of -23dBm.
Note 3: Out-of-band IIP3 is measured with two tones at fRF + 6MHz and fRF + 12MHz at a power level of -15dBm/tone. GC1 is set
for maximum attenuation (VGC1 = 2.7V) and GC2 is adjusted to achieve 0.5VP-P at the I/Q outputs for an input desired level
of -50dBm. fRF is set to 767MHz + 1/7MHz = 767.143MHz.
Note 4: GC1 is set for maximum attenuation (VGC1 = 2.7V). GC2 is adjusted to give the nominal I/Q output voltage level (0.5VP-P)
for a -50dBm desired tone at fRF = 550MHz. Two tones, 220MHz and 770MHz at -15dBm/tone, are then injected and the
571kHz IM2 levels are measured (with a 550.571MHz LO) at the I/Q outputs and IP2 is then calculated.
Note 5: Guaranteed by design and characterization.
Note 6: Guaranteed and tested at TA = +25°C and +85°C only.
_______________________________________________________________________________________
5
MAX2160/MAX2160EBG
AC ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics
(MAX2160 EV kit, TQFN package, VCC = +2.85V, default register settings, VGC1 = VCG2 = 0.3V, VIOUT = VQOUT = 0.5VP-P,
fLO = 767.714MHz, TA = +25°C, unless otherwise noted.)
SHUTDOWN-MODE SUPPLY CURRENT
vs. SUPPLY VOLTAGE
TA = +25°C
44
TA = -40°C
42
41
111
0.6
TA = +85°C
0.5
109
0.3
TA = -40°C
TA = +25°C
0.1
BBL[1:0] = 00
108
107
0
2.9
3.0
3.1
3.2
2.7
3.3
2.8
2.9
3.0
3.1
3.2
SUPPLY VOLTAGE (V)
RELATIVE GC1 GAIN RANGE
vs. GC1 VOLTAGE
RELATIVE GC2 GAIN RANGE
vs. GC2 VOLTAGE
TA = +85°C
-20
-30
TA = +25°C
-40
TA = -40°C
-10
-20
-30
TA = +85°C
-40
TA = +25°C
-50
FIXED VGC2
1.0
1.5
2.0
2.5
1.0
30
20
2.0
2.5
3.0
470
0
520
CLOSED-LOOP POWER CONTROL
fLO = 767.714MHz
f1 = fLO - 100kHz, f2 = fLO - 200kHz
-40
-60
-80
0
-100
570
620
670
720
770
INPUT RETURN LOSS vs. FREQUENCY
-20
10
TA = -40°C
FREQUENCY (MHz)
IN-BAND IIP3 vs. INPUT POWER
IN-BAND IIP3 (dBm)
40
1.5
20
MAX2160 toc07
CLOSED-LOOP POWER CONTROL
TA = +25°C
VGC2 (V)
NOISE FIGURE vs. INPUT POWER
50
4
0
0.5
VGC1 (V)
60
5
1
FIXED VGC1
0
3.0
TA = +85°C
6
2
0
5
INPUT RETURN LOSS (dB)
0.5
770
7
3
MAX2160 toc08
0
720
8
-80
-50
670
9
TA = -40°C
-70
620
10
MAX2160 toc05
0
-60
570
NOISE FIGURE vs. FREQUENCY
10
RELATIVE GC2 GAIN RANGE (dB)
-10
520
FREQUENCY (MHz)
SUPPLY VOLTAGE (V)
0
470
3.3
NOISE FIGURE (dB)
2.8
MAX2160 toc04
2.7
110
0.4
0.2
40
RELATIVE GC1 GAIN RANGE (dB)
0.7
MAX2160 toc09
43
112
MAX2160 toc06
46
45
0.8
GAIN (dB)
TA = +85°C
47
0.9
SUPPLY CURRENT (µA)
SUPPLY CURRENT (mA)
48
113
MAX2160 toc02
49
VOLTAGE GAIN vs. FREQUENCY
1.0
MAX2160 toc01
50
MAX2160 toc03
RECEIVE-MODE SUPPLY CURRENT
vs. SUPPLY VOLTAGE
NOISE FIGURE (dB)
MAX2160/MAX2160EBG
ISDB-T Single-Segment Low-IF Tuners
10
15
20
25
30
35
40
45
-100 -90 -80 -70 -60 -50 -40 -30 -20 -10 0
INPUT POWER (dBm)
6
50
-120
-100
-80
-60
-40
INPUT POWER (dBm)
-20
0
470
520
570
620
670
FREQUENCY (MHz)
_______________________________________________________________________________________
720
770
ISDB-T Single-Segment Low-IF Tuners
-108
-109
-110
-111
-112
-113
-20
-30
-40
-2
-3
-4
-5
-6
-7
-8
-50
-114
-9
-115
-10
-60
520
570
620
670
720
770
0
250
500
750
1000
1250
100 200 300 400 500 600 700 800 900 10001100
1500
FREQUENCY (MHz)
FREQUENCY (kHz)
FREQUENCY (kHz)
GROUP-DELAY VARIATION
vs. BASEBAND FREQUENCY
IF FILTER 3dB FREQUENCY
vs. TEMPERATURE
PHASE NOISE AT 10kHz OFFSET
vs. CHANNEL FREQUENCY
400
200
0
-200
-400
-600
4
3
1
0
-1
-3
-800
-1000
-5
FREQUENCY (kHz)
UPPER 3dB CUTOFF
-2
-4
200 300 400 500 600 700 800 900 1000
LOWER 3dB CUTOFF
2
NORMALIZED TO TA = +25°C
-40
-20
0
20
40
-80
MAX2160 toc16
600
5
PHASE NOISE AT 10kHz OFFSET (dBc/Hz)
800
MAX2160 toc14
MAX2160 toc13
1000
NORMALIZED 3dB FREQUENCY (%)
470
GROUP-DELAY VARIATION (ns)
MAX2160 toc12
-1
NORMALIZED GAIN (dB)
-10
NORMALIZED GAIN (dB)
-107
0
MAX2160 toc11
-106
LO-TO-RFIN LEAKAGE (dBm)
0
MAX2160 toc10
-105
IF FILTER PASSBAND
FREQUENCY RESPONSE
IF FILTER
FREQUENCY RESPONSE
LO-TO-RFIN LEAKAGE vs. FREQUENCY
-82
-84
-86
-88
-90
-92
-94
-96
-98
-100
60
TEMPERATURE (°C)
80
100
470
520
570
620
670
720
770
CHANNEL FREQUENCY (MHz)
_______________________________________________________________________________________
7
MAX2160/MAX2160EBG
Typical Operating Characteristics (continued)
(MAX2160 EV kit, TQFN package, VCC = +2.85V, default register settings, VGC1 = VCG2 = 0.3V, VIOUT = VQOUT = 0.5VP-P,
fLO = 767.714MHz, TA = +25°C, unless otherwise noted.)
Typical Operating Characteristics (continued)
(MAX2160 EV kit, TQFN package, VCC = +2.85V, default register settings, VGC1 = VCG2 = 0.3V, VIOUT = VQOUT = 0.5VP-P,
fLO = 767.714MHz, TA = +25°C, unless otherwise noted.)
TUNING VOLTAGE vs. VCO FREQUENCY
VCO 1, SB 0-7
VCO 2, SB 0-7
2.5
MAX2160 toc15
3.0
VCO 3, SB 0-7
VCO 4, SB 0-7
VTUNE (V)
2.0
1.5
1.0
0.5
0
350
400
450
500
550
600
650
700
750
800
850
VCO FREQUENCY (MHz)
POWER-DETECTOR RESPONSE TIME
PHASE NOISE vs. OFFSET FREQUENCY
MAX2160 toc18
MAX2160 toc17
-50
-60
-70
PHASE NOISE (dBc/Hz)
MAX2160/MAX2160EBG
ISDB-T Single-Segment Low-IF Tuners
B
A
-80
-90
-100
-110
A: LOW = -60dBm RF INPUT POWER
HIGH = -20dBm RF INPUT POWER
B: POWER-DETECTOR OUTPUT VOLTAGE,
0.5V/div, CLOSED-LOOP POWER-CONTROL
DEFAULT ATTACK POINT
0.01µF LOOP CAPACITOR
-120
-130
-140
fLO = 575.714MHz (VCO 2, SB1)
-150
1
10
100
1000
200µs/div
OFFSET FREQUENCY (kHz)
8
_______________________________________________________________________________________
ISDB-T Single-Segment Low-IF Tuners
PIN
BUMP NO.
TQFN
WLP
1, 11, 15, 21,
24, 28, 30, 31
29, 33, 34, 35,
36, 45, 46
N.C.
2
2
TCXO
High-Impedance Buffer for External TCXO. When ENTCXO is pulled high, this input
is enabled for use with an external TCXO and the internal crystal oscillator is
disabled. Requires a DC-blocking capacitor.
3
11
XTAL
Crystal-Oscillator Interface. When ENTCXO is pulled low, this input is enabled for use
with an external parallel resonance mode crystal. See the Typical Operating Circuit.
4
—
GNDXTAL
Crystal-Oscillator Circuit Ground. Connect to the PC board ground plane.
5
12
VCCXTAL
DC Power Supply for Crystal-Oscillator Circuits. Connect to a +2.85V low-noise
supply. Bypass to GND with a 100pF capacitor connected as close to the pin as
possible. Do not share capacitor ground vias with other ground connections.
6
4
XTALOUT
Crystal Oscillator Buffer Output. A DC-blocking capacitor must be used when driving
external circuitry.
7
5
VCCDIG
8
14
SDA
2-Wire Serial Data Interface. Requires a pullup resistor to VCC.
9
7
SCL
2-Wire Serial Clock Interface. Requires a pullup resistor to VCC.
10
19
LTC
PLL Lock Time Constant. LTC sources current to an external charging capacitor to
set the time constant for the VCO autoselect (VAS) function. See the Loop Time
Constant Pin section in the Applications Information.
12
9
VCCBIAS
DC Power Supply for Bias Circuits. Connect to a +2.85V low-noise supply. Bypass to
GND with a 100pF capacitor connected as close to the pin as possible. Do not share
capacitor ground vias with other ground connections.
13
17
RFIN
Wideband 50Ω RF Input. Connect to an RF source through a DC-blocking capacitor.
14
22
SHDN
Device Shutdown. Logic-low turns off the entire device including the 2-wire
compatible bus. SHDN overrides all software shutdown modes.
16
24
VCCLNA
DC Power Supply for LNA. Connect to a +2.85V low-noise supply. Bypass to GND
with a 100pF capacitor connected as close to the pin as possible. Do not share
capacitor ground vias with other ground connections.
17
25
GC1
RF Gain-Control Input. High-impedance analog input, with a 0.3V to 2.7V operating
range. VGC1 = 0.3V corresponds to the maximum gain setting.
18
28
VCCMX
DC Power Supply for RF Mixer Circuits. Connect to a +2.85V low-noise supply.
Bypass to GND with a 100pF capacitor connected as close to the pin as possible.
Do not share capacitor ground vias with other ground connections.
19
38
PWRDET
Power-Detector Output. See the IF Power Detector section in the Applications
Information.
NAME
DESCRIPTION
No Connection. Connect to the PC board ground plane.
DC Power Supply for Digital Logic Circuits. Connect to a +2.85V low-noise supply.
Bypass to GND with a 100pF capacitor connected as close to the pin as possible.
Do not share capacitor ground vias with other ground connections.
_______________________________________________________________________________________
9
MAX2160/MAX2160EBG
Pin Description
ISDB-T Single-Segment Low-IF Tuners
MAX2160/MAX2160EBG
Pin Description (continued)
10
PIN
BUMP NO.
TQFN
WLP
20
39
VCCFLT
DC Power Supply for Baseband Filter Circuits. Connect to a +2.85V low-noise
supply. Bypass to GND with a 100pF capacitor connected as close to the pin as
possible. Do not share capacitor ground vias with other ground connections.
22
37
ENTCXO
XTAL/TCXO Select. Logic-high enables the TCXO input and disables the XTAL input.
Logic-low disables the TCXO input and enables the XTAL input. This pin is internally
pulled up to VCC.
23
47
GC2
Baseband Gain-Control Input. High-impedance analog input, with a 0.3V to 2.7V
operating range. VGC2 = 0.3V corresponds to the maximum gain setting.
25
44
IOUT
In-Phase Low-IF Output. Requires a DC-blocking capacitor.
26
—
GNDBB
27
43
QOUT
Quadrature Low-IF Output. Requires a DC-blocking capacitor.
29
41
VCCBB
DC Power Supply for Baseband Circuits. Connect to a +2.85V low-noise supply.
Bypass to GND with a 100pF capacitor connected as close to the pin as possible.
Do not share capacitor ground vias with other ground connections.
32
30
VCOBYP
Internal VCO Bias Bypass. Bypass directly to GNDVCO with a 470nF capacitor
connected as close to the pin as possible. Do not share capacitor ground vias with
other ground connections. See the Layout Considerations section.
33
26
VCCVCO
DC Power Supply for VCO Circuits. Connect to a +2.85V low-noise supply. Bypass
directly to GNDVCO with a 100pF capacitor connected as close to the pin as
possible. Do not share capacitor ground vias with other ground connections.
34
23
GNDVCO
VCO Circuit Ground. Connect to the PC board ground plane. See the Layout
Considerations section.
35
32
VTUNE
36
20
GNDTUNE
37
18
TEST
NAME
DESCRIPTION
Ground for Baseband Circuits. Connect to the PC board ground plane.
High-Impedance VCO Tune Input. Connect the PLL loop filter output directly to this
pin with the shortest connection as possible.
Ground for VTUNE. Connect to the PC board ground plane. See the Layout
Considerations section.
Test Output. Used as a test output for various internal blocks. See Table 2.
38
16
CPOUT
Charge-Pump Output. Connect this output to the PLL loop filter input with the
shortest connection possible.
39
10
VCCCP
DC Power Supply for Charge-Pump Circuits. Connect to a +2.85V low-noise supply.
Bypass to GND with a 100pF capacitor connected as close to the pin as possible.
Do not share capacitor ground vias with other ground connections.
40
1
GNDCP
Charge-Pump Circuit Ground. Connect to the PC board ground plane. See the
Layout Considerations section.
EP
—
GND
Exposed Paddle (TQFN Only). Solder evenly to the board’s ground plane for proper
operation.
—
3, 6, 8, 13, 15,
27, 31, 40, 42
GND
Ground. Connect to the PC board ground plane.
—
21
GNDLNA
Ground for LNA. Connect to ground with trace.
______________________________________________________________________________________
ISDB-T Single-Segment Low-IF Tuners
All registers must be written after power-up and no earlier than 100µs after power-up.
ble registers include a test register, a PLL register, a
VCO register, a control register, a XTAL divide register,
an R-divider register, and two N-divider registers. The
read-only registers include two status registers.
Register Descriptions
The MAX2160/EBG include eight programmable registers and two read-only registers. The eight programma-
Table 1. Register Configuration
MSB
LSB
REGISTER
NUMBER
REGISTER
NAME
READ/
WRITE
REGISTER
ADDRESS
D7
D6
D5
D4
D3
D2
D1
1
TEST
WRITE
0x00
TUN2
TUN1
TUN0
FLTS
MXSD
D2
D1
D0
2
PLL
WRITE
0x01
CP1
CP0
CPS
EPB
RPD
NPD
TON
VAS
DATA BYTE
D0
3
VCO
WRITE
0x02
VCO1
VCO0
VSB2
VSB1
VSB0
ADL
ADE
LTC
4
CONTROL
WRITE
0x03
MOD
BBL1
BBL0
HSLS
PD2
PD1
PD0
EPD
5
XTAL DIVIDE
WRITE
0x04
XD4
XD3
XD2
XD1
XD0
PWDN
STBY
QOFF
6
R-DIVIDER
WRITE
0x05
R7
R6
R5
R4
R3
R2
R1
R0
7
N-DIVIDER MSB
WRITE
0x06
N12
N11
N10
N9
N8
N7
N6
N5
8
N-DIVIDER LSB
WRITE
0x07
N4
N3
N2
N1
N0
X
X
X
9
STATUS BYTE-1
READ
—
X
X
X
CP1
CP0
PWR
VASA
VASE
10
STATUS BYTE-2
READ
—
VCO1
VCO0
VSB2
VSB1
VSB0
ADC2
ADC1
ADC0
Table 2. Test Register
BIT NAME
BIT LOCATION
(0 = LSB)
RECOMMENDED
DEFAULT
FUNCTION
Set the baseband bandpass filter center frequency. This filter’s center frequency
is trimmed at the factory, but may be manually adjusted by clearing the FLTS bit
and programming the TUN[2:0] bits as follows:
000 = 0.75 x fO
001 = 0.80 x fO
010 = 0.86 x fO
011 = 0.92 x fO
100 = fO (nominal center frequency of 571kHz)
101 = 1.08 x fO
110 = 1.19 x fO
111 = 1.32 x fO
TUN[2:0]
7, 6, 5
000
FLTS
4
1
Selects which registers set the baseband bandpass filter center frequency.
1 = selects internal factory-set register
0 = selects manual trim register TUN[2:0]
______________________________________________________________________________________
11
MAX2160/MAX2160EBG
Detailed Description
MAX2160/MAX2160EBG
ISDB-T Single-Segment Low-IF Tuners
Table 2. Test Register (continued)
BIT NAME
BIT LOCATION
(0 = LSB)
RECOMMENDED
DEFAULT
MXSD
3
0
D[2:0]
2, 1, 0
000
FUNCTION
Used for factory trimming of the baseband filters.
1 = disables the quadrature mixers for filter tuning
0 = enables the quadrature mixers
Control diagnostic features as follows:
000 = normal operation
001 = force charge-pump source current
010 = force charge-pump sink current
011 = force charge-pump high-impedance state
100 = power-detector RMS voltage at PWRDET
101 = N-divider output at TEST pin
110 = R-divider output at TEST pin
111 = local oscillator output at TEST pin
Table 3. PLL Register
BIT NAME
CP[1:0]
7, 6
RECOMMENDED
DEFAULT
FUNCTION
11
Set the charge-pump current.
00 = ±1.5mA
01 = ±2mA
10 = ±2.5mA
11 = ±3mA
CPS
5
1
Sets the charge-pump current selection mode between automatic and manual.
0 = charge-pump current is set manually through the CP[1:0] bits
1 = charge-pump current is automatically selected based on ADC read values
in both VAS and manual VCO selection modes
EPB
4
1
Controls the charge-pump prebias function.
0 = disables the charge-pump prebias function
1 = enables the charge-pump prebias function
RPD
3
0
Sets the prebias on-time control from reference divider.
0 = 280ns
1 = 650ns
NPD
2
0
Sets the prebias on-time control from VCO/LO divider.
0 = 500ns
1 = 1000ns
TON
1
0
Sets the charge-pump on-time control.
0 = 2.5ns
1 = 5ns
1
Controls the VCO autoselect (VAS) function.
0 = disables the VCO autoselect function and allows manual VCO selection
through the VCO[1:0] and VSB[2:0] bits
1 = enables the on-chip VCO autoselect state machine
VAS
12
BIT LOCATION
(0 = LSB)
0
______________________________________________________________________________________
ISDB-T Single-Segment Low-IF Tuners
BIT NAME
VCO[1:0]
VSB[2:0]
ADL
BIT LOCATION
(0 = LSB)
7, 6
5, 4, 3
2
RECOMMENDED
DEFAULT
FUNCTION
11
Control which VCO is activated when using manual VCO programming mode.
This will also serve as the starting point for the VCO autoselect mode.
00 = select VCO 0
01 = select VCO 1
10 = select VCO 2
11 = select VCO 3
011
Select a particular sub-band for each of the on-chip VCOs. Together with the
VCO[2:0] bits a manual selection of a VCO and a sub-band can be made. This
will also serve as the starting point for the VCO autoselect mode.
000 = select sub-band 0
001 = select sub-band 1
010 = select sub-band 2
011 = select sub-band 3
100 = select sub-band 4
101 = select sub-band 5
110 = select sub-band 6
111 = select sub-band 7
0
Enables or disables the VCO tuning voltage ADC latch when the VCO autoselect
mode (VAS) is disabled.
0 = disables the ADC latch
1 = latches the ADC value
ADE
1
0
Enables or disables VCO tuning voltage ADC read when the VCO autoselect
mode (VAS) is disabled.
0 = disables ADC read
1 = enables ADC read
LTC
0
0
Sets the source current for the VAS time constant.
0 = 1µA
1 = 2µA
______________________________________________________________________________________
13
MAX2160/MAX2160EBG
Table 4. VCO Register
MAX2160/MAX2160EBG
ISDB-T Single-Segment Low-IF Tuners
Table 5. Control Register
BIT NAME
BIT LOCATION
(0 = LSB)
RECOMMENDED
DEFAULT
MOD
7
0
Sets the modulation mode and the baseband gain step.
0 = selects QAM mode and disables the 7dB gain step
1 = selects QPSK mode and adds 7dB of gain in the baseband stages
FUNCTION
BBL[1:0]
6, 5
10
Set the bias current for the baseband circuits to provide for fine linearity
adjustments.
00 = lower linearity
01 = nominal linearity
10 = medium linearity
11 = high linearity
HSLS
4
1
Selects between high-side and low-side LO injection.
0 = low-side injection
1 = high-side injection
14
PD[2:0]
3, 2, 1
011
EPD
0
0
Set the AGC attack point (at RFIN).
000 = -62dBm
001 = -60dBm
010 = -58dBm
011 = -56dBm
100 = -54dBm
101 = -52dBm
110 = -50dBm
111 = -48dBm
Enables or disables the power-detector circuit.
0 = disables the power-detector circuit for low-current mode
1 = enables the power-detector circuit
______________________________________________________________________________________
ISDB-T Single-Segment Low-IF Tuners
BIT NAME
XD[4:0]
PWDN
BIT LOCATION
(0 = LSB)
7–3
2
RECOMMENDED
DEFAULT
00001
MAX2160/MAX2160EBG
Table 6. XTAL Divide
FUNCTION
Set the crystal divider ratio for XTALOUT.
00000 = XTALOUT buffer disabled (off)
00001 = divide-by-1
00010 = divide-by-2
00011 = divide-by-3
00100 = divide-by-4
00101 through 11110 = all divide values from 3 (00101) to 30 (11110)
11111 = divide-by-31
0
Software power-down control.
0 = normal operation
1 = shuts down the entire chip but leaves the 2-wire bus active and maintains
the current register states
STBY
1
0
Software standby control.
0 = normal operation
1 = disables the signal path and frequency synthesizer leaving only the 2-wire
bus, crystal oscillator, XTALOUT buffer, and XTALOUT buffer divider active
QOFF
0
0
Enables and disables the Q-channel output.
0 = Q channel enabled
1 = Q channel disabled
Table 7. R-Divider Register
BIT NAME
BIT LOCATION
(0 = LSB)
RECOMMENDED
DEFAULT
R[7:0]
7–0
0x38
FUNCTION
Set the PLL reference-divider (R) number. Default R-divider value is 56 decimal.
R can range from 22 to 182 decimal.
Table 8. N-Divider MSB Register
BIT
NAME
BIT LOCATION
(0 = LSB)
RECOMMENDED
DEFAULT
N[12:5]
7–0
0x53
FUNCTION
Set the most significant bits of the PLL integer-divider number (N). Default
integer-divider value is N = 2687 decimal. N can range from 829 to 5374.
Table 9. N-Divider LSB Register
BIT NAME
BIT LOCATION
(0 = LSB)
RECOMMENDED
DEFAULT
N[4:0]
7–3
11111
X
2, 1, 0
X
FUNCTION
Set the least significant bits of the PLL integer-divider number (N). Default
integer-divider value is N = 2687 decimal. N can range from 829 to 5374.
Unused.
______________________________________________________________________________________
15
MAX2160/MAX2160EBG
ISDB-T Single-Segment Low-IF Tuners
Table 10. Status Byte-1 Register
BIT NAME
BIT LOCATION
(0 = LSB)
X
7, 6, 5
CP[1:0]
4, 3
FUNCTION
Unused.
Reflect the charge-pump current setting. See Table 3 for CP[1:0] definition.
PWR
2
Logic-high indicates power has been cycled, but the device has the default programming. A STOP
condition while in read mode resets this bit.
VASA
1
Indicates whether VCO automatic selection was successful.
0 = indicates the autoselect function is disabled or unsuccessful VCO selection
1 = indicates successful VCO automatic selection
VASE
0
Status indicator for the autoselect function.
0 = indicates the autoselect function is active
1 = indicates the autoselect process is inactive
Table 11. Status Byte-2 Register
BIT NAME
BIT LOCATION
(0 = LSB)
VCO[1:0]
7, 6
VSB[2:0]
5, 4, 3
Indicate which sub-band of a particular VCO has been selected by either the autoselect state
machine or by manual selection when the VAS state machine is disabled. See Table 4 for VSB[2:0]
definition.
ADC[2:0]
2, 1, 0
Indicate the 3-bit ADC conversion of the VCO tuning voltage (VTUNE).
FUNCTION
Indicate which VCO has been selected by either the autoselect state machine or by manual
selection when the VAS state machine is disabled. See Table 4 for VCO[1:0] definition.
2-Wire Serial Interface
The MAX2160/EBG uses a 2-wire I2C-compatible serial
interface consisting of a serial-data line (SDA) and a
serial-clock line (SCL). SDA and SCL facilitate bidirectional communication between the MAX2160/EBG and
the master at clock frequencies up to 400kHz. The
master initiates a data transfer on the bus and generates the SCL signal to permit data transfer. The
MAX2160/EBG behave as a slave device that transfers
and receives data to and from the master. SDA and
SCL must be pulled high with external pullup resistors
(1kΩ or greater) for proper bus operation.
One bit is transferred during each SCL clock cycle. A
minimum of nine clock cycles is required to transfer a
byte in or out of the MAX2160/EBG (8 bits and an
ACK/NACK). The data on SDA must remain stable during the high period of the SCL clock pulse. Changes in
SDA while SCL is high and stable are considered con-
16
trol signals (see the START and STOP Conditions section). Both SDA and SCL remain high when the bus is
not busy.
START and STOP Conditions
The master initiates a transmission with a START condition (S), which is a high-to-low transition on SDA while
SCL is high. The master terminates a transmission with
a STOP condition (P), which is a low-to-high transition
on SDA while SCL is high.
Acknowledge and Not-Acknowledge Conditions
Data transfers are framed with an acknowledge bit
(ACK) or a not-acknowledge bit (NACK). Both the master and the MAX2160/EBG (slave) generate acknowledge bits. To generate an acknowledge, the receiving
device must pull SDA low before the rising edge of the
acknowledge-related clock pulse (ninth pulse) and
keep it low during the high period of the clock pulse.
______________________________________________________________________________________
ISDB-T Single-Segment Low-IF Tuners
A write cycle begins with the bus master issuing a START
condition followed by the seven slave address bits and a
write bit (R/W = 0). The MAX2160/EBG issue an ACK if
the slave address byte is successfully received. The bus
master must then send to the slave the address of the first
register it wishes to write to (see Table 1 for register
addresses). If the slave acknowledges the address, the
master can then write one byte to the register at the specified address. Data is written beginning with the most significant bit. The MAX2160/EBG again issue an ACK if the
data is successfully written to the register. The master
can continue to write data to the successive internal registers with the MAX2160/EBG acknowledging each successful transfer, or it can terminate transmission by
issuing a STOP condition. The write cycle will not terminate until the master issues a STOP condition.
Slave Address
The MAX2160/EBG have a 7-bit slave address that
must be sent to the device following a START condition
to initiate communication. The slave address is internally programmed to 1100000. The eighth bit (R/W) following the 7-bit address determines whether a read or
write operation will occur.
The MAX2160/EBG continuously await a START condition followed by its slave address. When the device
recognizes its slave address, it acknowledges by
pulling the SDA line low for one clock period; it is ready
to accept or send data depending on the R/W bit
(Figure 1).
Figure 2 illustrates an example in which registers 0
through 2 are written with 0x0E, 0xD8, and 0xE1,
respectively.
SLAVE ADDRESS
S
1
1
0
0
0
0
0
R/W
ACK
1
2
3
4
5
6
7
8
9
P
SDA
SCL
Figure 1. MAX2160 Slave Address Byte
START
WRITE DEVICE
ADDRESS
R/W
1100000
0
ACK
WRITE REGISTER
ADDRESS
0x00
ACK
WRITE DATA TO
REGISTER 0x00
ACK
WRITE DATA TO
REGISTER 0x01
0x0E
0xD8
ACK
WRITE DATA TO
REGISTER 0x02
ACK
STOP
0xE1
Figure 2. Example: Write Registers 0 through 2 with 0x0E, 0xD8, and 0xE1, Respectively
______________________________________________________________________________________
17
MAX2160/MAX2160EBG
Write Cycle
When addressed with a write command, the
MAX2160/EBG allow the master to write to a single register or to multiple successive registers.
To generate a not-acknowledge condition, the receiver
allows SDA to be pulled high before the rising edge of
the acknowledge-related clock pulse, and leaves SDA
high during the high period of the clock pulse.
Monitoring the acknowledge bits allows for detection of
unsuccessful data transfers. An unsuccessful data transfer happens if a receiving device is busy or if a system
fault has occurred. In the event of an unsuccessful data
transfer, the bus master must reattempt communication
at a later time.
MAX2160/MAX2160EBG
ISDB-T Single-Segment Low-IF Tuners
START
WRITE DEVICE
ADDRESS
R/W
1100000
1
ACK
READ FROM STATUS
BYTE-1 REGISTER
ACK
READ FROM STATUS
BYTE-2 REGISTER
ACK/
NACK
STOP
Figure 3. Example: Receive Data from Read Registers
Read Cycle
There are only two registers on the MAX2160/EBG that
are available to be read by the master. When
addressed with a read command, the MAX2160/EBG
send back the contents of both read registers (STATUS
BYTE-1 and STATUS BYTE-2).
A read cycle begins with the bus master issuing a
START condition followed by the seven slave address
bits and a read bit (R/W = 1). If the slave address byte
is successfully received, the MAX2160/EBG issue an
ACK. The master then reads the contents of the STATUS BYTE-1 register, beginning with the most significant bit, and acknowledges if the byte is received
successfully. Next, the master reads the contents of the
STATUS BYTE-2 register. At this point the master can
issue an ACK or NACK and then a STOP condition to
terminate the read cycle.
Figure 3 illustrates an example in which the read registers are read by the master.
Applications Information
RF Input (RFIN)
The MAX2160/EBG are internally matched to 50Ω and
requires a DC-blocking capacitor (see the Typical
Operating Circuit).
RF Gain Control (GC1)
The MAX2160/EBG feature a variable-gain low-noise
amplifier that provides 43dB of RF gain-control range.
The voltage control (VGC1) range is 0.3V (minimum
attenuation) to 2.7V (maximum attenuation).
IF Power Detector
The MAX2160/EBG include a true RMS power detector
at the mixer output. The power-detector circuit is
enabled or disabled with the EPD bit in the control register. The attack point can be set through the PD[2:0]
18
bits in the control register (see Table 5 for a summary
of attack point settings).
The PWRDET pin output can be configured to provide
either a voltage output (directly from the RMS powerdetector stage) or current output (default) through the
diagnostic bits D[2:0] in the test register.
Closed-Loop RF Power Control
The default mode of the IF power detector is current output mode. Closed-loop RF power control is formed by
connecting the PWRDET pin directly to the GC1 pin. A
shunt capacitor to ground is added to set the closedloop response time (see the Typical Operating Circuit).
The recommended capacitor value of 10nF provides a
response time of 0.1ms.
Closed-loop RF power control can also be formed using
the baseband processor and the power detector in voltage output mode. In this configuration, the processor
senses the power detector’s output voltage and uses this
information to drive the GC1 pin directly. Voltage output
mode is enabled by setting the D[2:0] bits in the test register to 100. In voltage mode, the PWRDET pin outputs a
scaled DC voltage proportional to the RF input power.
For the RF input range of -62dBm to -48dBm, the DC
output voltage ranges from 84mV to 420mV.
High-Side and Low-Side LO Injection
The MAX2160/EBG allow selection between high-side
and low-side LO injection through the HSLS bit in the
control register. High-side injection is the default setting
(HSLS = 1).
Q-Channel Shutdown
The Q channel low-IF output of the MAX2160/EBG can
be turned off with the QOFF bit in the XTAL divide register for use with single low-IF input demodulators (use I
channel only). Turning off the Q channel reduces the
supply current by approximately 3mA.
______________________________________________________________________________________
ISDB-T Single-Segment Low-IF Tuners
During the selection process, the VASE bit in the
STATUS BYTE-2 register is cleared to indicate the automatic selection function is active. Upon successful
completion, bits VASE and VASA are set and the VCO
and sub-band selected are reported in the STATUS
BYTE-2 register (see Table 11). If the search is unsuccessful, VASA is cleared and VASE is set. This indicates that searching has ended but no good VCO has
been found, and occurs when trying to tune to a frequency outside the VCO’s specified frequency range.
Fixed IF Gain Step
Charge-Pump Select (CPS)
To maintain the best possible sensitivity for both QPSK
and QAM signals, the MAX2160/EBG include a control
bit (MOD) to increase the gain of the baseband stage
by approximately 7dB. This gain step is intended to be
used when receiving QPSK signals. Set the MOD bit to
one in QPSK receive mode, set the MOD bit to zero in
QAM receive mode.
The MAX2160/EBG also allow for manual selection of the
charge-pump current (CPS = 0) or automatic selection
based on the final VTUNE ADC read value (CPS = 1).
When in manual mode, the charge-pump current is programmed by bits CP[1:0] with the 2-wire bus. When in
automatic selection mode, the CP[1:0] bits are automatically set according to the ADC table (see Tables 12 and
13). The selected charge-pump current (manually or
automatically) is reported in the STATUS BYTE-1 register.
VCO Autoselect (VAS)
The MAX2160/EBG include four VCOs with each VCO
having eight sub-bands. The local oscillator frequency
can be manually selected by programming the
VCO[1:0] and VSB[2:0] bits in the VCO register. The
selected VCO and sub-band is reported in the STATUS
BYTE-2 register (see Table 11).
Alternatively, the MAX2160/EBG can be set to automatically choose a VCO and VCO sub-band. Automatic
VCO selection is enabled by setting the VAS bit in the
PLL register, and is initiated once the N-divider LSB
register word is loaded. In the event that only the Rdivider register or N-divider MSB register word is
changed, the N-divider LSB word must also be loaded
(last) to initiate the VCO autoselect function. The VCO
and VCO sub-band that are programmed in the
VCO[1:0] and VSB[2:0] bits serve as the starting point
for the automatic VCO selection process.
Table 12. Charge-Pump Current Selection
3-Bit ADC
The MAX2160/EBG have an internal 3-bit ADC connected to the VCO tune pin (VTUNE). This ADC can be
used for checking the lock status of the VCOs.
Table 13 summarizes the ADC trip points, associated
charge-pump settings (when CPS = 1), and the VCO
lock indication. The VCO autoselect routine will only
select a VCO in the “VAS locked” range. This allows
room for a VCO to drift over temperature and remain in
a valid “locked” range.
The ADC must first be enabled by setting the ADE bit in
the VCO register. The ADC reading is latched by a subsequent programming of the ADC latch bit (ADL = 1).
The ADC value is reported in the STATUS BYTE-2
register (see Table 11).
Table 13. ADC Trip Points, Associated
Charge-Pump Settings, and Lock Status
LOCK STATUS
VASA
VTUNE (VT)
CP[1:0]
CPS
CHARGE-PUMP VALUES
(CP[1:0])
ADC[2:0]
VAS
VT < 0.41V
000
00
Out of Lock
0
0
X
Values programmed with 2-wire bus
0.41V < VT < 0.6V
001
00
Locked
0
1
X
Values selected by ADC read
0.6V < VT < 0.9V
010
00
VAS Locked
1
0
X
Values programmed with 2-wire bus
0.9V < VT < 1.3V
011
01
VAS Locked
1
1
0
Values programmed with 2-wire bus
1.3V < VT < 1.7V
100
10
VAS Locked
1
1
1
Values selected by ADC read
1.7V < VT < 1.9V
101
11
VAS Locked
1.9V < VT <
VCC - 0.41V
011
11
Locked
VCC - 0.41V < VT
111
11
Out of Lock
______________________________________________________________________________________
19
MAX2160/MAX2160EBG
IF Filter Tuning
The center frequency of the baseband bandpass filter
is tuned to 571kHz during production at the factory.
However, the factory-set trim may be bypassed and the
filter’s center frequency can be adjusted through the
FLTS and TUN[2:0] bits in the test register. Setting the
FLTS bit sets the filter’s center frequency to the factoryset tuning, clearing the FLTS bit allows the filter’s center
frequency to be adjusted with the TUN[2:0] bits (see
Table 2).
MAX2160/MAX2160EBG
ISDB-T Single-Segment Low-IF Tuners
Loop Time Constant Pin (LTC)
Shutdown and Standby Modes
The LTC function sets the wait time for an ADC read
when in VCO autoselect mode. The time constant is set
by charging an external capacitor connected to the
LTC pin with a constant current source. The value of
the current source can be programmed to 1µA or 2µA
with the LTC bit in the VCO register (see Table 4).
The LTC time constant is determined by the following
equation:
Time constant = CLTC x 1.7 / ILTC
where:
CLTC = capacitor connected from the
LTC pin to ground.
ILTC = 1µA (LTC = 0) or 2µA (LTC = 1).
The MAX2160/EBG feature hardware- and softwarecontrolled shutdown mode as well as a software-controlled standby mode. Driving the SHDN pin low with bit
EPD = 0 places the device in hardware shutdown
mode. In this mode, the entire device including the 2wire-compatible interface is turned off and the supply
current drops to less than 10µA. The hardware shutdown pin overrides the software shutdown and standby
modes.
Setting the PWDN bit in the XTAL divide register
enables power-down mode. In this mode, all circuitry
except for the 2-wire-compatible bus is disabled, allowing for programming of the MAX2160/EBGs’ registers
while in shutdown. Setting the STBY bit in the XTAL
divide register puts the device into standby mode, during which only the 2-wire-compatible bus, the crystal
oscillator, the XTAL buffer, and the XTAL buffer-divider
are active.
Setting CLTC equal to 1000pF gives a time constant
of 1.7ms with ILTC set to 1µA and 0.85ms with ILTC
set to 2µA.
ENTCXO
The MAX2160/EBG have both an integrated crystal
oscillator and a separate TCXO buffer amplfier. The
ENTCXO pin controls which reference source is used
(see Table 14).
XTALOUT Divider
A reference buffer/divider is provided for driving external devices. The divider can be set for any division ratio
from 1 to 31 by programming the XD[4:0] bits in the
XTAL divide register (see Table 6). The buffer can be
disabled by setting XD[4:0] to all zeros.
Table 14. Reference Source Selection
ENTCXO
FUNCTION
VCC
The TCXO input is enabled for use with an
external TCXO
GND
The XTAL input is enabled for use with an external
crystal
In all cases, register settings loaded prior to entering
shutdown are saved upon transition back to active
mode. Default register values are loaded only when
VCC is applied from a no-VCC state. The various powerdown modes are summarized in Table 15. Supply current fluctuations for nondefault register settings are
shown in Table 16.
Diagnostic Modes and Test Pin
The MAX2160/EBG have several diagnostic modes that
are controlled by the D[2:0] bits in the test register (see
Table 2). The local oscillator can be directed to the
TEST pin for LO measurements by setting the D[2:0] bits
to all ones. In this mode, the supply current will increase
by approximately 10mA. The TEST pin requires a 10kΩ
pullup resistor to VCC for proper operation.
Table 15. Power-Down Modes
POWER-DOWN CONTROL
MODE
CIRCUIT STATES
SHDN PIN
PWDN
BIT
STBY
BIT
SIGNAL
PATH
2-WIRE
INTERFACE
XTAL
Normal
VCC
0
0
ON
ON
ON
DESCRIPTION
All circuits active
Shutdown
GND
X
X
OFF
OFF
OFF
All circuits disabled
Power-Down
VCC
1
0
OFF
ON
OFF
2-wire interface is active
Standby
VCC
0
1
OFF
ON
ON
2-wire interface, XTAL, and XTAL
buffer/divider are active
20
______________________________________________________________________________________
ISDB-T Single-Segment Low-IF Tuners
MODE
BIT CHANGE
TYPICAL ICC
TYPICAL ∆ICC FROM
NOMINAL
Default register settings
46.5mA
—
QOFF = 1 (Q channel off)
—
-3.3mA
BBL[1:0] = 00 (lower linearity)
—
-2mA
BBL[1:0] = 01 (nominal linearity)
—
-1mA
BBL[1:0] = 11 (high linearity)
—
+1mA
MOD = 1 (7dB baseband gain step enabled)
—
+0.3mA
Receive
EPD = 1 (power detector enabled)
—
+1mA
EPB = 0 (charge-pump prebias disabled)
—
+5.1mA
XD[4:0] = 00000 (XTALOUT buffer disabled)
—
-40µA
Shutdown
SHDN = GND
1µA
—
Standby
STBY = 1
2.2mA
—
Power-Down
PWDN = 1
13.5µA
—
Layout Considerations
The EV kit serves as a guide for PC board layout. Keep
RF signal lines as short as possible to minimize losses
and radiation. Use controlled impedance on all highfrequency traces. For proper operation of the TQFN
package, the exposed paddle must be soldered evenly
to the board’s ground plane. Use abundant vias
beneath the exposed paddle for maximum heat dissipation. Use abundant ground vias between RF traces
to minimize undesired coupling. Bypass each VCC pin
to ground with a 100pF capacitor placed as close to
the pin as possible.
In addition, the ground returns for the VCO, VTUNE,
and charge pump require special layout consideration.
The VCOBYP capacitor (C37) and the VCCVCO bypass
capacitor (C19) ground returns must be routed back to
the GNDVCO pin and then connected to the overall
ground plane at that point (GNDVCO). All loop filter
component grounds (C27–C30) and the VCCCP
bypass capacitor (C17) ground must all be routed
together back to the GNDCP pin. GNDTUNE must also
be routed back to the GNDCP pin along with all other
grounds from the PLL loop filter. The GNDCP pin must
then be connected to the overall ground plane. Figure
4 shows a schematic drawing of the required layout
connections. Refer to the MAX2160 evaluation kit for a
recommended board layout.
R21
ROUTE GNDTUNE, C17, AND ALL
LOOP FILTER COMPONENT GROUNDS TO
GNDCP.
R22
C29
VCC
C30
R20
C28
VCC
C27
ROUTE C19 AND C37 TO GNDVCO.
C17
C19
CONNECT GNDVCO TO THE BOARD'S
GROUND PLANE.
CONNECT GNDCP TO THE BOARD'S
GROUND PLANE.
40
39
38
37
36
35
34
33
32
GNDCP
VCCCP
CPOUT
TEST
GNDTUNE
VTUNE
GNDVCO
VCCVCO
VCOBYP
C37
Figure 4. Ground Return Layout Connections for the VCO, Charge Pump, and VTUNE
______________________________________________________________________________________
21
MAX2160/MAX2160EBG
Table 16. Typical Supply Current Fluctuations for Nondefault Register Settings
ISDB-T Single-Segment Low-IF Tuners
MAX2160/MAX2160EBG
Pin Configurations/Functional Diagrams (continued)
TOP VIEW
41
32
VCCBB
VTUNE
42
33
GND
N.C.
30
23
26
20
VCOBYP VCCVCO GNDVCO GNDTUNE
16
1
CPOUT
GNDCP
10
43
34
29
N.C.
N.C.
44
11
3
XTAL
GND
12
4
MAX2160EBG+
QOUT
VCCXTAL XTALOUT
18
35
IOUT
2
VCCCP TCXO
45
N.C. ALIGNMENT MARK
(NOT BUMPED)
36
N.C.
N.C.
TEST
13
5
GND VCCDIG
22
19
14
6
SHDN
LTC
SDA
GND
46
37
15
7
N.C.
ENTCXO
GND
SCL
47
38
GC2
PWRDET
28
25
8
VCCMX
GC1
GND
40
39
31
27
GND
VCCFLT
GND
GND
24
21
VCCLNA GNDLNA
17
9
RFIN
VCCBIAS
WLP
22
______________________________________________________________________________________
ISDB-T Single-Segment Low-IF Tuners
R21
R22
C28
C29
C30
R20
C27
VCC
VCC
C19
C17
40
1
SCL
SERIAL-DATA
INPUT/OUTPUT
C18
LTC
N.C.
VCOBYP
VCCVCO
25
6
7
8
9
10
SERIAL-CLOCK
INPUT
N.C.
11
VCC
24
12
MAX2160
23
PWRDET
EP
22
21
13
14
15
16
17
18
19
VCCBB
C16
N.C.
C22
QOUT
GNDBB
QUADRATURE
OUTPUT
(OPTIONAL)
C21
IOUT
IN-PHASE
OUTPUT
N.C.
R18
GC2
VGC2
C15
ENTCXO
N.C.
20
VCC
C12
C7
GNDVCO
VTUNE
GNDTUNE
TEST
CPOUT
26
VCC
N.C.
VCCFLT
R13
÷
5
PWRDET
R12
29
VCCMX
SDA
31
28
GC1
C5
32
TANK
VCCLNA
VCCDIG
33
27
N.C.
XTALOUT
BUFFERED
CRYSTAL OUTPUT
34
4
SHDN
C3
C4
35
DIV4
RFIN
VCCXTAL
VCC
36
30
3
INTERFACE LOGIC
AND CONTROL
GNDXTAL
37
ADC
XTAL
38
FREQUENCY
SYNTHESIZER
TCXO 2
VCC
39
VCCBIAS
N.C.
VCCCP
GNDCP
C37
VCC
VCC
C9
RF INPUT
C10
C8
ON
C14
SHDN
OFF
NOTE: SHOWN FOR TQFN PACKAGE.
Chip Information
TRANSISTOR COUNT: 23,510
PROCESS: BiCMOS
______________________________________________________________________________________
23
MAX2160/MAX2160EBG
Typical Operating Circuit
MAX2160/MAX2160EBG
ISDB-T Single-Segment Low-IF Tuners
Package Information
For the latest package outline information and land patterns, go to www.maxim-ic.com/packages. Note that a “+”, “#”, or “-” in the
package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the
package regardless of RoHS status.
PACKAGE TYPE
24
PACKAGE CODE
DOCUMENT NO.
40 Thin QFN-EP
T4066-2
21-0141
WLP
B08133+1
21-0173
______________________________________________________________________________________
ISDB-T Single-Segment Low-IF Tuners
REVISION
NUMBER
REVISION
DATE
4
12/06
—
5
10/09
Corrected Charge-Pump Output Current limits for bits CP[1:0] = 01 in Electrical
Characteristics table
DESCRIPTION
PAGES
CHANGED
1, 2, 3, 24, 25
4
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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 ____________________ 25
© 2009 Maxim Integrated Products
Maxim is a registered trademark of Maxim Integrated Products, Inc.
MAX2160/MAX2160EBG
Revision History