LINER LTM9003

Electrical Specifications Subject to Change
LTM9003
12-Bit Digital Pre-Distortion
Receiver Subsystem
FEATURES
DESCRIPTION
n
The LTM®9003 is a 12-bit digital pre-distortion receiver
subsystem for the transmit path of cellular basestations.
Utilizing an integrated system in a package (SiP) tech-nology, it includes a downconverting mixer, wideband filter
and analog-to-digital converter (ADC). The system is tuned
for an intermediate frequency (IF) of 184MHz and a signal
bandwidth of up to 125MHz. The 12-bit ADC samples at
rates up to 250Msps. Contact Linear Technology regarding customization.
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n
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n
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Fully Integrated Receiver Subsystem for Digital
Pre-Distortion Applications
Down-Converting Mixer with Wide RF Frequency
Range: 400MHz to 3.8GHz
125MHz Wide Bandpass Filter, <0.5dB Passband
Ripple
Low Power ADC with Up to 12-Bit Resolution,
250Msps Sample Rate
–145.5dBm/Hz Input Noise Floor, 25.8dBm IIP3
1.5W Total Power Consumption
50Ω Single-Ended RF and LO Ports
Internal Bypass Capacitance, No External
Components
ADC Clock Duty Cycle Stabilizer
11.25mm × 15mm LGA package
The high signal level downconverting active mixer is optimized for high linearity, wide dynamic range IF sampling
applications. It includes a differential LO buffer amplifier
driving a double-balanced mixer. Broadband, integrated
transformers on the RF and LO inputs provide single
ended 50Ω interfaces. The RF and LO inputs are internally
matched to 50Ω from 1.1GHz to 1.8GHz.
APPLICATIONS
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The CLK input controls converter operation and may be
driven differentially or single-ended. An optional clock duty
cycle stabilizer allows high performance at full speed for
a wide range of clock duty cycles.
Transmit Observation Path Receivers
Digital Pre-Distortion (DPD) Receivers
Wideband Receiver
Wideband Instrumentation
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of Linear
Technology Corporation. All other trademarks are the property of their respective owners.
Protected by U.S. Patents including 5481178, 6580258, 6304066, 6127815, 6498466, 6611131.
TYPICAL APPLICATION
FFT of 4-Channel WCDMA Input at 1.95GHz
–40
3.3V
PA
–50
2.5V
–60
OVDD = 2.5V
(dB)
LTM9003
D11
•
•
•
D0
RF
–70
–80
LVDS
–90
–100
DGND
LO
GND
ENC–
ENC+
9003 TA01
–110
154
164
174
184
194
IF FREQUENCY (MHz)
204
214
9003 TA01b
9003p
1
LTM9003
ABSOLUTE MAXIMUM RATINGS
PIN CONFIGURATION
(Notes 1, 2)
Supply Voltage (VCC1)
LTM9003-AA ........................................ –0.3V to 3.6V
LTM9003-AB ........................................ –0.3V to 5.5V
Supply Voltage (VCC2) ................................ –03V to 5.5V
Supply Voltage (VDD, OVDD) ..................... –0.3V to 2.8V
Digital Output Ground Voltage (OGND) ........ –0.3V to 1V
LO Input Power (380MHz to 4.2GHz) ...................10dBm
LO Input DC Voltage............................. –1V to VCC1 + 1V
RF Input Power (400MHz to 3.8GHz) ...................15dBm
RF Input DC Voltage ............................................... ±0.1V
Mixer Enable Voltage .....................–0.3V to VCC1 + 0.3V
AMP Enable Input Current.................................... ±10mA
Digital Input Voltage..................... –0.3V to (VDD + 0.3V)
Digital Output Voltage ................ –0.3V to (OVDD + 0.3V)
Operating Ambient Temperature Range
LTM9003CV ................................................. 0 to 70°C
LTM9003IV ..............................................–40 to 85°C
Storage Temperature Range ...................... –40 to 125°C
Maximum Junction Temperature .......................... 125°C
TOP VIEW
LO
ALL OTHERS = GND
J
H
RF
OVDD
G
F
VCC1
E
D
VDD
ENC–
ENC+
C
VCC2
B
A
1
2
3
4
5
6
7
AMP_EN MIX_EN
8
9
10
11
12
DATA, CONTROL
LGA PACKAGE
108-LEAD (15mm s 11.25mm s 2.32mm)
TJMAX = 125°C, θJA = 15°C/W, θJC = 6°C/W
DERIVED FROM TBDmm × TBDmm PCB WITH 4 LAYERS WEIGHT = TBD g
CAUTION: The RF and LO inputs are sensitive to electrostatic discharge (ESD). It is very important that proper ESD
precautions be observed when handling the LTM9003.
ORDER INFORMATION
LEAD FREE FINISH
TRAY
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTM9003CV-AA#PBF
LTM9003CV-AA#PBF
LTM9003V AA
108-Lead (11.25mm × 15mm × 2.3mm) LGA
0°C to 70°C
LTM9003IV-AA#PBF
LTM9003IV-AA#PBF
LTM9003V AA
108-Lead (11.25mm × 15mm × 2.3mm) LGA
–40°C to 85°C
LTM9003CV-AB#PBF
LTM9003CV-AB#PBF
LTM9003V AB
108-Lead (11.25mm × 15mm × 2.3mm) LGA
0°C to 70°C
LTM9003IV-AB#PBF
LTM9003IV-AB#PBF
LTM9003V AB
108-Lead (11.25mm × 15mm × 2.3mm) LGA
–40°C to 85°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
This product is only offered in trays. For more information go to: http://www.linear.com/packaging/
9003p
2
LTM9003
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. (Note 3)
PARAMETER
CONDITIONS
MIN
RF Input Frequency Range
LTM9003-AA
No External Matching (Midband)
With External Matching (Low Band or High Band)
400
LTM9003-AB
No External Matching (Midband)
With External Matching (Low Band or High Band)
400
LTM9003-AA
No External Matching
With External Matching
380
LTM9003-AB
No External Matching
With External Matching
380
LO Input Frequency Range
RF Input Return Loss
TYP
MAX
UNITS
3800
MHz
MHz
3700
MHz
MHz
1100 to 1800
1100 to 1800
800 to 3500
MHz
MHz
900 to 3500
MHz
MHz
ZO = 50Ω, 1100MHz to 1800MHz (No External Matching)
LTM9003-AA
LTM9003-AB
>12
>12
dB
dB
ZO = 50Ω, 900MHz to 3500MHz (No External Matching)
LTM9003-AA
LTM9003-AB
>10
>10
dB
dB
RF Input Power for –1dBFS
LTM9003-AA
LTM9003-AB
–1.8
–1.8
dBm
dBm
LO Input Power
1200MHz to 4200MHz, LTM9003-AA or
1200MHz to 3500MHz, LTM9003-AB
380MHz to 1200MHz
LO Input Return Loss
LO to RF Leakage
RF to LO Isolation
–8
–5
–3
0
2
5
dBm
dBm
LTM9003-AA
fLO = 380MHz to 1600MHz
fLO = 1600MHz to 4000MHz
<–50
<–45
dBm
dBm
LTM9003-AB
fLO = 400MHz to 2100MHz
fLO = 2100MHz to 3200MHz
<–44
<–36
dBm
dBm
LTM9003-AA
fRF = 400MHz to 1700MHz
fRF = 1700MHz to 3800MHz
>50
>42
dBm
dBm
LTM9003-AB
fRF = 400MHz to 2200MHz
fRF = 2200MHz to 3700MHz
>43
>38
dBm
dBm
CONVERTER CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. (Note 3)
PARAMETER
CONDITIONS
MIN
l
Resolution (No Missing Codes)
TYP
12
MAX
UNITS
Bits
Integral Linearity Error (Note 4)
IF = 184.32MHz
TBD
LSB
Differential Linearity Error
IF = 184.32MHz
TBD
LSB
9003p
3
LTM9003
FILTER CHARACTERISTICS
The l denotes the specifications which apply over the full operating temperature
range, otherwise specifications are at TA = 25°C.
PARAMETER
CONDITIONS
Center Frequency
LTM9003-Ax
MIN
184.32
TYP
MAX
UNITS
MHz
Lower 3dB Bandedge
LTM9003-Ax
84
MHz
Upper 3dB Bandedge
LTM9003-Ax
304
MHz
Lower 20dB Stopband
LTM9003-Ax
40
MHz
Upper 20dB Stopband
LTM9003-Ax
450
MHz
Passband Flatness
129MHz to 239.6MHz, LTM9003-Ax
174MHz to 194MHz, LTM9003-Ax
0.5
0.15
dB
dB
Group Delay Flatness
129MHz to 239.6MHz, LTM9003-Ax
174MHz to 194MHz, LTM9003-Ax
1.2
0.1
ns
ns
Absolute Delay
LTM9003-Ax
2.7
ns
DYNAMIC ACCURACY
The l denotes the specifications which apply over the full operating temperature range,
otherwise specifications are at TA = 25°C. (Note 3)
SYMBOL PARAMETER
CONDITIONS
SNR
RF = 1950MHz, LO = 1766MHz
RF = 1889MHz, LO = 1766MHz
RF = 2011MHz, LO = 1766MHz
IIP3
IIP2
SFDR
Signal-to-Noise Ratio at –1dBFS
Input 3rd Order Intercept, 2-Tone
Input 2nd Order Intercept, 1-Tone
Spurious Free Dynamic Range 2nd or 3rd
Harmonic at –1dBFS
S/(N+D)
MAX
UNITS
dB/Hz
dB/Hz
dB/Hz
LTM9003-AA
RF = 1948MHz, 1952MHz, LO = 1766MHz
25.8
dBm
LTM9003-AB
RF = 1948MHz, 1952MHz, LO = 1766MHz
26.5
dBm
LTM9003-AA
RF = 1950MHz, LO = 1766MHz
61
dBm
LTM9003-AB
RF = 1950MHz, LO = 1766MHz
67
dBm
LTM9003-AA
RF = 1889MHz, LO = 1766MHz
RF = 1950MHz, LO = 1766MHz
RF = 2011MHz, LO = 1766MHz
l
TBD
52.4
TBD
RF = 1950MHz, LO = 1766MHz
RF = 1889MHz, LO = 1766MHz
RF = 2011MHz, LO = 1766MHz
l
TBD
Signal-to-Noise Plus Distortion Ratio at –1dBFS RF = 1950MHz, LO = 1766MHz
RF = 1889MHz, LO = 1766MHz
RF = 2011MHz, LO = 1766MHz
l
RF = 1950MHz, LO = 1766MHz
67.4
dB
dB
dB
61
65
71.5
dB
dB
dB
63
61
dB
dB
dB
57
58
dB
dB
dB
TBD
l
Spurious Free Dynamic Range 4th or Higher at
–1dBFS
TYP
143.7
143.7
LTM9003-AB
RF = 1889MHz, LO = 1766MHz
RF = 1950MHz, LO = 1766MHz
RF = 2011MHz, LO = 1766MHz
SFDR
MIN
l
TBD
IMD3
Intermodulation Distortion at –7dBFS per Tone
–67
dB
ACPR
Adjacent Channel Power Ratio at 2.4dBm per
Carrier, Four Carriers
58.5
dB
ALTCPR
Alternate Channel Power Ratio at 2.4dBm per
Carrier, Four Carriers
63.3
dB
9003p
4
LTM9003
DIGITAL INPUTS AND OUTPUTS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. (Note 3)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Encode Inputs (ENC–, ENC+)
VID
Differential Input Voltage
VICM
Common Mode Input Voltage
Internally Set
Externally Set
l
0.2
l
1.2
V
1.5
1.5
2
V
V
RIN
Input Resistance
4.8
Ω
CIN
Input Capacitance
2
pF
Logic Inputs (OE, SHDN)
VIH
High Level Input Voltage
VDD = 2.5V
l
VIL
Low Level Input Voltage
VDD = 2.5V
l
IIN
Input Current
VIN = 0V to VDD
l
CIN
Input Capacitance
(Note 5)
VIH
High Level Input Voltage
VCC1 = 3.3V, LTM9003-AA
VCC1 = 5V, LTM9003-AB
VIL
Low Level Input Voltage
VCC1 = 3.3V, LTM9003-AA
VCC1 = 5V, LTM9003-AB
IIN
Input Current
VIN = 0V to VCC1, LTM9003-AA
1.7
V
–10
0.7
V
10
μA
3
pF
Mixer Enable
2.7
3
V
V
0.3
0.3
53
90
V
V
μA
Turn-On Time
2.8
ms
Turn-Off Time
2.9
ms
Amplifier Enable
VIH
High Level Input Voltage
VCC2 = 3.3V
VIL
Low Level Input Voltage
VCC2 = 3.3V
IIN
Input Current
VIN = 0V to VCC2
2.7
V
53
0.3
V
90
μA
1
μA
Control Inputs (SENSE, MODE, LVDS)
l
ISENSE
SENSE Input Leakage
0V < SENSE < 1V
IMODE
MODE Pull-Down Current to GND
See Pin Descriptions for Voltage Levels
–1
7
μA
ILVDS
LVDS Pull-Down Current to GND
See Pin Descriptions for Voltage Levels
7
μA
Logic Outputs (LVDS Mode)
OVDD = 2.5V
VOD
Differential Output Voltage
100Ω Differential Load
l
247
350
454
VOS
Output Common Mode Voltage
100Ω Differential Load
l
1.125
1.250
1.375
mV
V
9003p
5
LTM9003
POWER REQUIREMENTS
The l denotes the specifications which apply over the full operating temperature
range, otherwise specifications are at TA = 25°C. (Note 3)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
VCC1
Mixer Supply Range
LTM9003-AA
LTM9003-AB
2.9
4.5
3.3
5
3.9
5.25
V
V
VCC2
Amplifier Supply Range
2.8
3.3
5.25
V
VDD
ADC Analog Supply Voltage
2.375
2.5
2.625
V
ICC1
Mixer Supply Current
82
78
92
88
l
MIX_EN = 3V, LTM9003-AA
MIX_EN = 5V, LTM9003-AB
l
mA
mA
ICC1(SHDN)
Mixer Shutdown Supply Current
MIX_EN = 0V
l
100
μA
ICC2
Amplifier Supply Current
AMP_EN = 3V
l
104
140
mA
ICC2(SHDN)
Amplifier Shutdown Supply Current AMP_EN = 0V
l
3
5
mA
IDD(ADC)
ADC Supply Current
l
285
320
PD(SHDN)
ADC Shutdown Power
SHDN = 3V, OE = 3V, No CLK
TBD
mW
PD(NAP)
ADC Nap Mode Power
SHDN = 3V, OE = 0V, No CLK
TBD
mW
mA
LVDS Output Mode
OVDD
ADC Digital Output Supply Voltage
l
2.375
2.5
2.625
V
IOVDD(ADC)
ADC Digital Output Supply Current
l
58
70
mA
PD(ADC)
ADC Power Dissipation
l
858
975
mW
PD(TOTAL)
Total Power Dissipation
SHDN = 0V, MIX_EN = AMP_EN = 3V, fSAMPLE = MAX
(LTM9003-AA)
(LTM9003-AB)
1472
1591
mW
mW
9003p
6
LTM9003
TIMING CHARACTERISTICS
The l denotes the specifications which apply over the full operating temperature
range, otherwise specifications are at TA = 25°C. (Note 3)
SYMBOL
PARAMETER
fs
Sampling Frequency
CONDITIONS
MIN
tL
ENC Low Time
tH
ENC High Time
tJITTER
Sample-and-Hold Acquisition Delay Time Jitter
tAP
Sample-and-Hold Aperture Delay
tOE
Output Enable Delay
(Note 5)
l
tD
ENC to DATA delay
(Note 5)
l
tC
ENC to CLKOUT Delay
(Note 5)
l
DATA to CLKOUT Skew
(tC – tD) (Note 5)
l
–0.6
l
1
Duty Cycle Stabilizer Off (Note 5)
Duty Cycle Stabilizer On (Note 5)
l
l
1.9
1.5
Duty Cycle Stabilizer Off (Note 5)
Duty Cycle Stabilizer On (Note 5)
l
l
1.9
1.5
TYP
MAX
UNITS
250
MHz
2
2
500
500
ns
ns
2
2
500
500
ns
ns
95
fsRMS
0
ns
5
10
ns
1
1.7
2.8
ns
1
1.7
2.8
ns
0
0.6
ns
LVDS Output Mode
Rise Time
0.5
ns
Fall Time
0.5
ns
Pipeline Latency
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: All voltage values are with respect to ground with GND and OGND
wired together (unless otherwise noted).
5
Cycles
Note 3: VCC1 = VCC2 = 3.3V (LTM9003-AA) or VCC1 = 5V, VCC2 = 3.3V
(LTM9003-AB), VDD = 2.5V, OVDD = 2.5V, fSAMPLE = 250MHz, input range =
–1dBFS, differential ENC+/ENC– = 2VP–P sine wave, unless otherwise noted.
Note 4: Integral nonlinearity is defined as the deviation of a code from
a “best straight line” fit to the transfer curve. The deviation is measured
from the center of the quantization band.
Note 5: Guaranteed by design, not subject to test.
9003p
7
LTM9003
TIMING DIAGRAM
tAP
ANALOG
INPUT
N+4
N+2
N
N+3
tH
N+1
tL
ENC–
ENC+
tD
N–5
D0-D11, OF
CLKOUT–
N–4
N–3
N–2
N–1
tC
CLKOUT+
9003 TD01
LVDS Output Mode Timing
All Outputs Are Differential and Have LVDS Levels
9003p
8
LTM9003
TYPICAL PERFORMANCE CHARACTERISTICS
64k Point 2-Tone FFT,
LTM9003-AA
64k Point FFT, LTM9003-AA
0
fIN = 1948MHz,
–10 f = 1952MHz
IN
–20 –7dBFS PER TONE
SENSE
= VDD
–30
AMPLITUDE (dBFS)
–40
–50
–60
–70
–80
–60
–70
–100
–110
–110
100
120
–120
63
62
–80
–100
40
60
80
FREQUENCY (MHz)
64
–50
–90
61
0
20
40
60
80
FREQUENCY (MHz)
100
9003 G01
120
60
10
60
110 160 210 260 310 360 410
IF FREQUENCY (MHz)
9003 G02
IF Frequency Response,
LTM9003-AA
9003 G03
IF Frequency Response,
LTM9003-AA
0
0
–5
–0.5
–10
AMPLITUDE (dBFS)
20
65
–40
–90
AMPLITUDE (dBFS)
AMPLITUDE (dBFS)
–30
0
66
SNR (dBFS)
fIN = 1950MHz
–10 –1dBFS
–20 SENSE = VDD
–120
SNR vs Frequency, LTM9003-AA
0
–1.0
–1.5
–2.0
–15
–20
–25
–30
–35
–40
–2.5
–45
–3.0
110
135
160
185
210
IF FREQUENCY (MHz)
235
260
9003 G04
–50
10
60
110 160 210 260 310 360 410
IF FREQUENCY (MHz)
9003 G05
9003p
9
LTM9003
TYPICAL PERFORMANCE CHARACTERISTICS
64k Point 2-Tone FFT,
LTM9003-AB
64k Point FFT, LTM9003-AB
–40
–50
–60
–70
–80
–40
–60
–70
–80
–90
–100
–100
–110
–110
–120
40
60
80
FREQUENCY (MHz)
100
120
64
–50
–90
20
65
SNR (dBFS)
AMPLITUDE (dBFS)
AMPLITUDE (dBFS)
–30
0
66
fIN = 1948MHz,
–10 f = 1952MHz
IN
–20 –7dBFS PER TONE
SENSE
= VDD
–30
fIN = 1950MHz
–10 –1dBFS
–20 SENSE = VDD
–120
SNR vs Frequency, LTM9003-AB
0
0
63
62
61
20
0
40
60
80
FREQUENCY (MHz)
100
60
120
10
60
110 160 210 260 310 360 410
IF FREQUENCY (MHz)
9003 G07
9003 G06
IF Frequency Response,
LTM9003-AB
9003 G08
IF Frequency Response,
LTM9003-AB
0
0
–5
–10
AMPLITUDE (dBFS)
AMPLITUDE (dBFS)
–0.5
–1.0
–1.5
–2.0
–15
–20
–25
–30
–35
–40
–2.5
–45
–3.0
110
135
160
185
210
IF FREQUENCY (MHz)
235
260
9003 G09
–50
10
60
110 160 210 260 310 360 410
IF FREQUENCY (MHz)
9003 G10
9003p
10
LTM9003
PIN FUNCTIONS
VCC1 (Pins E1, E2, F2): 3.3V (LTM9003-AA) or 5V
(LTM9003-AB) Supply Voltage for the Mixer. VCC1 is
internally bypassed to GND.
VCC2 (Pins B1, B2): 3.3V Supply Voltage for the Amplifier.
VCC2 is internally bypassed to GND.
VDD (Pins D11, E7, E8): 2.5V Supply Voltage for ADC.
VDD is internally bypassed to GND.
OVDD (Pins G12, H9, H11): Positive Supply for the Output Drivers. Bypass to ground with 0.1μF ceramic chip
capacitor. OVDD can be 0.5V to 2.6V. OVDD is internally
bypassed to OGND.
GND (See Table for Locations): Module Ground.
OGND (Pins F12, H8, H10, H12, J12): Output Driver
Ground.
RF (Pin G1): Single-Ended Input for the RF Signal. This
pin is internally connected to the primary side of the RF
input transformer, which has low DC resistance to ground.
If the RF source is not DC blocked, then a series blocking
capacitor must be used. The RF input is internally matched
from 1.1GHz to 1.8GHz. Operation down to 400MHz or up
to 3.8GHz is possible with simple external matching.
LO (Pin J2): Single-Ended Input for the Local Oscillator
Signal. This pin is internally connected to the primary side
of the LO transformer, which is internally DC blocked. An
external blocking capacitor is not required. The LO input is
internally matched from 0.9GHz to 3.5GHz. Operation down
to 380MHz is possible with simple external matching.
MIX_EN (Pin F4): Mixer Enable Pin. Connecting MIX_EN
to VCC1 results in normal operation. Connecting MIX_EN
to GND disables the mixer. The MIX_EN pin should not
be left floating.
AMP_EN (Pin C3): Amplifier Enable Pin. This pin is
internally pulled high by a typically 30k resistor to VCC2.
Connecting AMP_EN to VCC2 results in normal operation.
Connecting AMP_EN to GND disables the amplifier.
ENC+ (Pin D12): ADC Encode Input. Conversion starts on
the positive edge.
SHDN (Pin B11): ADC Shutdown Mode Selection Pin. Connecting SHDN to GND and OE to GND results in normal
operation with the outputs enabled. Connecting SHDN to
GND and OE to VDD results in normal operation with the
outputs at high impedance. Connecting SHDN to VDD and
OE to GND results in nap mode with the outputs at high
impedance. Connecting SHDN to VDD and OE to VDD results
in sleep mode with the outputs at high impedance.
OE (Pin C11): Output Enable Pin. Refer to SHDN pin
function.
MODE (Pin C7): Output Format and Clock Duty Cycle
Stabilizer Selection Pin. Connecting MODE to GND selects
offset binary output format and turns the clock duty cycle
stabilizer off. 1/3 VDD selects offset binary output format
and turns the clock duty cycle stabilizer on. 2/3 VDD selects
2’s complement output format and turns the clock duty
cycle stabilizer on. VDD selects 2’s complement output
format and turns the clock duty cycle stabilizer off.
SENSE (Pin G7): Reference Programming Pin. Connecting
SENSE to VCM selects the internal reference and a ±0.5V
input range. VDD selects the internal reference and a ±1V
input range. An external reference greater than 0.5V and
less than 1V applied to SENSE selects an input range of
±VSENSE. ±1V is the largest valid input range.
LVDS (Pin D7): Output Mode Selection Pin. Connect LVDS
to VDD.
Digital Outputs
D0–/D0+ – D11–/D11+ (See Table for Locations): LVDS
Digital Outputs. All LVDS outputs require differential 100Ω
termination resistors at the LVDS receiver. D11–/D11+ is
the MSB.
CLKOUT–/CLKOUT+ (Pins J10/J11): LVDS Data Valid
Output. Latch data on rising edge of CLKOUT–, falling
edge of CLKOUT+.
OF–/OF+ (Pins E5/F5): LVDS Over/Under Flow Output.
High when an over or under flow has occurred.
ENC– (Pin E12): ADC Encode Complement Input. Conversion starts on the negative edge. Bypass to ground with
0.1μF ceramic for single-ended ENCODE signal.
9003p
11
LTM9003
PIN FUNCTIONS
Pin Configuration
J
GND
LO
GND
GND
GND
H
GND
GND
GND
GND
GND
G
RF
GND
GND
GND
GND
D9+
D8+
D6+
D6–
CLKOUT+
CLKOUT–
OGND
D9–
D8–
OGND
OVDD
OGND
OVDD
OGND
D10–
SENSE
D7+
D7–
D5+
D5–
OVDD
F
GND
VCC1
GND
MIX_EN
OFP
D10+
GND
GND
GND
GND
GND
OGND
E
VCC1
VCC1
GND
GND
OFN
D11–
VDD
VDD
GND
GND
GND
ENC–
D
GND
GND
GND
GND
GND
D11+
LVDS
D4+
D3+
D1+
VDD
ENC+
C
GND
GND
AMP_EN
GND
GND
GND
MODE
D4–
D3–
D1–
OE
GND
B
VCC2
VCC2
GND
GND
GND
GND
GND
GND
D2+
D0+
SHDN
GND
A
GND
GND
GND
GND
GND
GND
GND
GND
D2–
D0–
GND
GND
1
2
3
4
5
6
7
8
9
10
11
12
Top View of LGA Package (Looking Through Component)
BLOCK DIAGRAM
VCC1
VCC2
VDD
MODE
LVDS
OE
SHDN
OVDD
RF
OF
INPUT
S/H
BPF
PIPELINED
ADC SECTIONS
CONTROL
LOGIC
LPF
OUTPUT
DRIVERS
D11
…
D0
CLKOUT
SHIFT REGISTER/
ERROR CORRECTION
1.25V
REFERENCE
OGND
INTERNAL
CLOCK SIGNALS
RANGE
SELECT
REFH REFL
REFERENCE
BUFFER
DIFFERENTIAL INPUT
LOW JITTER
CLOCK DRIVER
DIFFERENTIAL
REFERENCE
AMPLIFIER
MIX_EN
LO
AMP_EN
SENSE
100Ω
GND
ENC–
ENC+
9003 BD01
Figure 1. Simplified Block Diagram
9003p
12
LTM9003
OPERATION
DESCRIPTION
The LTM9003 is an integrated system in a package (SiP)
that includes a high-speed 12-bit A/D converter, a wideband
filter and an active mixer. The LTM9003 is designed for IF
sampling, digital pre-distortion (DPD) applications, also
known as transmit observation path receivers, with RF input
frequencies up to 3.8GHz. Typical applications include multicarrier base stations and telecom test instrumentation.
Digital pre-distortion is a technique often used in thirdgeneration (3G) wireless base stations to improve the
linearity of power amplifiers (PA). Improved PA linearity
allows for a lower power PA to be used and therefore save
a significant amount of power in the base station. The DPD
receiver captures the PA output, digitizes it and feeds it back
where the distortion can be analyzed. A complementary
distortion is then introduced to the transmit DAC thereby
pre-distorting the signal.
A significant factor in PA linearity is the distortion caused
by the odd order intermodulation (IM) products. The bandwidth to be digitized is equivalent to the signal bandwidth
multiplied by the order of the IM product to be canceled.
For example, four carrier WCDMA consumes 20MHz of
signal bandwidth; therefore, to capture the fifth order IM
product requires 100MHz. The Nyquist theory requires that
the ADC sample rate be at least twice that frequency.
However, simply doubling the captured bandwidth to set
the sample rate may not be the best choice. Selecting the
exact ADC sample rate and intermediate frequency (IF)
depends on other factors within the system. To simplify
filtering, the sample rate is often set at a multiple of the
chip rate. The chip rate for WCDMA is 3.84MHz; selecting an ADC sample rate of 64 times the chip rate gives
245.76Msps. Placing the IF at 3/4ths the sample rate (fS)
gives 184.32MHz and allows the entire bandwidth to fall
within the second Nyquist zone. Many other frequency
plans may be acceptable.
The following sections describe in further detail the operation of each functional element of the LTM9003. The SiP
technology allows the LTM9003 to be customized and
this is described in the Semi-Custom Options section.
The outline of the remaining sections follows the basic
functional elements as shown in Figure 2.
MIXER
FILTER
IF
AMPLIFIER
FILTER
ADC
9003 F02
Figure 2. Basic Functional Elements
The mixer dominates the noise figure calculation as would
be expected. The overall gain is optimized for the dynamic
range of the ADC relative to the RF input level allowed by
the mixer. The equivalent cascaded noise figure is 9.1dB
(LTM9003-AA) and 9.9dB (LTM9003-AB). The bandpass
filter is a second order L-C filter following the mixer and
a lowpass filter following the amplifier provides anti-alias
and noise limiting.
SEMI-CUSTOM OPTIONS
The μModule construction affords a new level of flexibility
in application-specific standard products. Standard ADC
and amplifier components can be integrated regardless
of their process technology and matched with passive
components to a particular application. The LTM9003-AA,
as the first example, is configured with a 12-bit ADC
sampling at rates up to 250Msps. The total system gain
is approximately 10.8dB. The IF is fixed by the bandpass
filter at 184MHz with 125MHz bandwidth. The RF range
is matched for 1.1GHz to 1.8GHz with low side LO.
However, other options are possible through Linear
Technology’s semi-custom development program. Linear
Technology has in place a program to deliver other speed,
resolution, IF range, gain and filter configurations for nearly
any specified application. These semi-custom designs are
based on existing ADCs and amplifiers with an appropriately
modified matching network. The final subsystem is then
tested to the exact parameters defined for the application.
The final result is a fully integrated, accurately tested and
optimized solution in the same package. For more details
on the semi-custom receiver subsystem program, contact
Linear Technology.
Down-Converting Mixer
The mixer stage consists of a high linearity double-balanced mixer, RF buffer amplifier, high speed limiting LO
buffer amplifier and bias/enable circuits. The RF and LO
9003p
13
LTM9003
OPERATION
inputs are both single ended. Low side or high side LO
injection can be used.
The mixer’s RF input consists of an integrated transformer
and a high linearity differential amplifier. The primary
terminals of the transformer are connected to the RF
input (Pin G1) and ground. The secondary side of the
transformer is internally connected to the amplifier’s differential inputs.
The mixer’s LO input consists of an integrated transformer
and high speed limiting differential amplifiers. The amplifiers are designed to precisely drive the mixer for the
highest linearity and the lowest noise figure.
Wideband Filter
Most of the IF filtering is done between the mixer and
the IF amplifier. This network is a 2nd order Chebychev
bandpass section, designed for 0.1dB passband ripple.
The 3dB bandwidth is 220MHz, centered at 184MHz, see
Figure 3. Additional lowpass filtering is done just before
the ADC. This filter serves to bandlimit the out of band
noise entering the converter, as well as to isolate the
output of the IF amplifier from the sampling action of the
converter.
0
–5
AMPLITUDE (dBFS)
–10
–15
–20
–25
–30
–35
–40
–45
–50
10
60
110 160 210 260 310 360 410
IF FREQUENCY (MHz)
Analog to Digital Converter
As shown in Figure 1, the analog-to-digital converter (ADC)
is a CMOS pipelined multistep converter. The converter
has five pipelined ADC stages; a sampled analog input will
result in a digitized value five cycles later (see the Timing Diagram section). The encode input is differential for
improved common mode noise immunity. The ADC has
two phases of operation, determined by the state of the
differential ENC+/ENC– input pins. For brevity, the text will
refer to ENC+ greater than ENC– as ENC high and ENC+
less than ENC– as ENC low.
Each pipelined stage shown in Figure 1 contains an ADC,
a reconstruction DAC and an interstage residue amplifier.
In operation, the ADC quantizes the input to the stage and
the quantized value is subtracted from the input by the
DAC to produce a residue. The residue is amplified and
output by the residue amplifier. Successive stages operate
out of phase so that when the odd stages are outputting
their residue, the even stages are acquiring that residue
and visa versa.
When ENC is low, the analog input is sampled differentially
directly onto the input sample-and-hold capacitors, inside
the “Input S/H” shown in the Block Diagram. At the instant
that ENC transitions from low to high, the sampled input is
held. While ENC is high, the held input voltage is buffered
by the S/H amplifier which drives the first pipelined ADC
stage. The first stage acquires the output of the S/H during this high phase of ENC. When ENC goes back low, the
first stage produces its residue which is acquired by the
second stage. At the same time, the input S/H goes back
to acquiring the analog input. When ENC goes back high,
the second stage produces its residue which is acquired
by the third stage. An identical process is repeated for the
third and fourth stages, resulting in a fourth stage residue
that is sent to the fifth stage ADC for final evaluation.
9003 F03
Figure 3. IF Filter Response
Each ADC stage following the first has additional range to
accommodate flash and amplifier offset errors. Results
from all of the ADC stages are digitally synchronized such
that the results can be properly combined in the correction
logic before being sent to the output buffer.
9003p
14
LTM9003
APPLICATIONS INFORMATION
RF Input Port
The mixer’s RF input is shown in Figure 4 and is internally
matched from 1.1GHz to 1.8GHz, requiring no external
components over this frequency range. The input return
loss, shown in Figure 5, is typically 12dB at the band edges.
The input match at the lower band edge can be optimized
with a shunt 3.3pF capacitor at Pin G1, which improves
the 0.8GHz return loss to greater than 25dB. Likewise,
the 2GHz match can be improved to greater than 25dB
with a series 3.9nH inductor and a 1pF shunt capacitor.
Measured RF input return losses for these three cases are
plotted in Figure 5.
LOW-PASS MATCH
FOR 450MHz, 900MHz
and 3.6GHz RF
ZO = 50Ω
L = L (mm)
RFIN
LTM9003
TO
MIXER
RF
C5
9003 F04
RFIN
C5
L5
HIGH-PASS MATCH
FOR 2.6GHz RF
AND WIDEBAND RF
Figure 4. RF Input Schematic
RF PORT RETURN LOSS (dB)
0
–5
–10
–15
–20
–25
–30
100
2GHz MATCH
(3.9nH + 1pF)
NO MATCHING
ELEMENTS
800MHz MATCH
(3.3pF)
1000
FREQUENCY (MHz)
10000
9003 F05
Figure 5. RF Input Return Loss with and without Matching
This series transmission line/shunt capacitor matching
topology allows the LTM9003 to be used for multiple
frequency standards without circuit board layout modifications. The series transmission line can also be replaced
with a series chip inductor for a more compact layout.
RF input impedance and S11 versus frequency (with no
external matching) are listed in Table 1 and referenced
to Pin G1. The S11 data can be used with a microwave
circuit simulator to design custom matching networks and
simulate board-level interfacing to the RF input filter.
Table 1a. RF Input Impedance vs Frequency (LTM9003-AA)
S11
FREQUENCY
(MHz)
INPUT IMPEDANCE
MAG
ANGLE
500
20.3 + j7
0.57
143
600
23.6 + j6.7
0.53
137.9
700
27.1 + j6.1
0.48
132.7
800
30.8 + j5.3
0.43
127
900
34.9 + j4.2
0.38
120.4
1000
39.4 + j2.9
0.33
112.6
1100
44.6 + j1.4
0.28
102.8
1200
50.1
0.22
89.8
1300
56 – j1
0.17
70.4
1400
61.5 – j1.2
0.14
42.2
1500
66 – j0.3
0.14
6.6
1600
68.7 + j1.4
0.17
–21.5
1700
69 + j3.2
0.22
–41
1800
67.5 + j4.5
0.27
–54
1900
64.3 + j4.7
0.32
–64.3
2000
60.8 + j4.1
0.36
–72.2
2100
56.7 + j2.8
0.4
–79.5
2200
52.7 + j1.2
0.43
–85.8
2300
48.6 – j0.6
0.46
–92.1
2400
44.7 – j2.3
0.48
–98
2500
40.8 – j4
0.5
–104.3
2600
37 – j5.3
0.51
–110.5
2700
33.1 – j6.3
0.52
–117.2
2800
29.4 – j6.9
0.53
–124.3
2900
26 – j7
0.53
–131.7
3000
22.9 – j6.7
0.53
–139.6
9003p
15
LTM9003
APPLICATIONS INFORMATION
Table 1b. RF Input Impedance vs Frequency (LTM9003-AB)
LTM9003
EXTERNAL
MATCHING
FOR LO < 1GHz
S11
FREQUENCY
(MHz)
INPUT IMPEDANCE
MAG
ANGLE
500
19.8 + j7.3
0.59
143
600
22.7 + j7
0.55
138.4
700
25.7 + j6.6
0.51
133.9
800
28.8 + j5.9
0.47
129.2
900
32.3 + j5.1
0.42
123.9
1000
36.1 + j3.9
0.38
117.9
1100
40.5 + j2.6
0.32
110.6
1200
45.4 + j1.1
0.26
101.3
1300
50.8 – j0.2
0.2
87.6
1400
56.3 – j0.9
0.15
65.6
1500
61.4 – j0.7
0.12
27.5
1600
65.3 + j0.5
0.14
–13.1
1700
67.4 + j2.4
0.19
–37.9
1800
67.3 + j4.1
0.25
–52.4
1900
65.7 + j5.1
0.31
–61.9
2000
63.2 + j5.2
0.37
–68.9
2100
60.4 + j4.7
0.42
–74.4
LOIN
L4
TO
MIXER
LO
C4
LIMITER
REGULATOR
VREF
VCC2
9003 F06
Figure 6. LO Input Schematic
Custom matching networks can be designed using the port
impedance data listed in Table 2. This data is referenced
to the LO pin with no external matching.
Table 2a. LO Input Impedance vs Frequency (LTM9003-AA)
S11
FREQUENCY
(MHz)
INPUT IMPEDANCE
MAG
ANGLE
500
10.3 – j6.1
0.73
–159.1
600
9.7 + j2.2
0.68
172.4
700
18.7 + j8.2
0.64
141.8
800
37 + j6.2
0.6
108.4
2200
57.6 + j3.7
0.46
–79.1
2300
55 + j2.6
0.49
–83
2400
52.4 + j1.3
0.51
–86.7
900
64.5 – j9.9
0.59
72.7
109.7 – j42.2
0.6
38.3
2500
49.9
0.53
–90.1
1000
2600
47.4 – j1.4
0.54
–93.7
1100
206.6 – j35.9
0.63
7.9
183.8 + j70
0.66
–17.1
0.68
–37.3
2700
44.8 – j2.7
0.55
–97.3
1200
2800
41.9 – j3.9
0.55
–101.6
1300
115.4 + j59.4
2900
39 – j5
0.55
–106.3
1400
86.7 + j35.2
0.7
–53.7
3000
35.7 – j5.9
0.54
–111.9
1500
70.7 + j18.5
0.71
–67.4
1600
59.3 + j7.4
0.7
–79.2
LO Input Port
1700
50.2 + j0.2
0.7
–89.7
The mixer’s LO input, shown in Figure 6, is internally
matched from 0.9GHz to 3.5GHz. LO input matching near
600MHz requires the series inductor (L4)/shunt capacitor (C4) network shown in Figure 6. Likewise, the 2GHz
match can be improved by using L4 = 2.7μH, C4 = 0.5pF.
Measured LO input return losses for these three cases
are plotted in Figure 7.
1800
42.6 – j4.5
0.68
–99.6
1900
35.9 – j7.2
0.66
–109.2
2000
30.2 – j8.3
0.63
–118.9
2100
25.6 – j8.1
0.59
–129.2
2200
22.4 – j6.7
0.54
–140.3
2300
20.8 – j4.6
0.48
–152.3
2400
21.5 – j2.1
0.42
–165.5
2500
24.2
0.35
–179.8
2600
28.9 + j1.3
0.28
163.9
2700
35.3 + j1.5
0.21
145.1
2800
42.6 + j0.9
0.16
121.1
2900
50.3
0.12
88.6
3000
57.7 – j0.6
0.1
45.8
The optimum LO drive is –3dBm for LO frequencies above
1.2GHz, although the amplifiers are designed to accommodate several dB of LO input power variation without significant
mixer performance variation. Below 1.2GHz, 0dBm LO drive
is recommended for optimum noise figure, although –3dBm
will still deliver good conversion gain and linearity.
9003p
16
LTM9003
APPLICATIONS INFORMATION
Table 2b. LO Input Impedance vs Frequency (LTM9003-AB)
S11
Mixer Enable Interface
The voltage necessary to turn on the mixer is 2.7V. To disable the mixer, the enable voltage must be less than 0.3V.
If the MIX_EN pin is allowed to float, the mixer will tend
to remain in its last operating state. Thus it is not recommended that the enable function be used in this manner.
If the shutdown function is not required, then the MIX_EN
pin should be connected directly to VCC1.
FREQUENCY
(MHz)
INPUT IMPEDANCE
MAG
ANGLE
500
14.3 – j7.5
0.68
–150.6
600
12.6 – j2.4
0.61
–170.4
700
15.8 + j1.9
0.53
170.8
800
22.7 + j4.1
0.44
151.5
900
32.5 + j3.8
0.35
130.2
1000
44.2 + j1.3
0.25
104.9
1100
56.3 – j1.2
0.18
70.3
Amplifier Enable Interface
1200
66 – j1.3
0.15
26.4
1300
70.7 + j1
0.18
–12.8
1400
69.9 + j3.1
0.21
–37.8
The AMP_EN pin self-biases to VCC2 through a 30k resistor. The pin must be pulled below 0.8V in order to disable
the amplifier.
1500
66 + j3.7
0.25
–54.1
1600
61.8 + j3.3
0.27
–65.5
1700
58.1 + j2.4
0.28
–73.4
1800
54.9 + j1.5
0.29
–79.8
1900
52.7 + j0.8
0.28
–84.2
2000
50.7 + j0.2
0.28
–88.5
2100
49.4 – j0.2
0.27
–91.4
2200
47.8 – j0.5
0.25
–95.5
2300
46.7 – j0.7
0.23
–98.9
2400
45.7 – j0.8
0.2
–103.3
2500
45.5 – j0.7
0.17
–106.8
2600
46.4 – j0.4
0.13
–107.1
2700
48.7 – j0.1
0.1
–97.9
2800
50.9 + j0.1
0.09
–84.2
2900
52.9 + j0.3
0.09
–72.5
3000
54.6 + j0.5
0.11
–66.7
Driving the ADC Clock Input
The noise performance of the ADC can depend on the
encode signal quality as much as on the analog input. The
ENC+/ENC– inputs are intended to be driven differentially,
primarily for noise immunity from common mode noise
sources. Each input is biased through a 4.8k resistor to
a 1.5V bias. The bias resistors set the DC operating point
for transformer coupled drive circuits and can set the logic
threshold for single-ended drive circuits.
Any noise present on the encode signal will result in additional aperture jitter that will be RMS summed with the
inherent ADC aperture jitter.
In applications where jitter is critical (high input frequencies) take the following into consideration:
1. Differential drive should be used.
2. Use as large an amplitude as possible; if transformer
coupled use a higher turns ratio to increase the
amplitude.
0
RETURN LOSS (dB)
–5
600MHz MATCH
(6.8nH + 5.6pF)
–10
3. If the ADC is clocked with a sinusoidal signal, filter the
encode signal to reduce wideband noise.
–15
–20
–25
–30
100
NO MATCHING
ELEMENTS
2GHz MATCH
(2.7nH + 0.5pF)
1000
FREQUENCY (MHz)
10000
9003 F07
4. Balance the capacitance and series resistance at both
encode inputs so that any coupled noise will appear at
both inputs as common mode noise. The encode inputs
have a common mode range of 1.2V to 2.0V. Each input
may be driven from ground to VDD for single-ended
drive.
Figure 7. LO Input Return Loss with and without Matching
9003p
17
LTM9003
APPLICATIONS INFORMATION
LTM9003
VDD
TO INTERNAL
ADC CIRCUITS
CLOCK
INPUT
VDD
T1
MA/COM
0.1μF ETC1-1-13
•
1.5V
BIAS
4.8k
ENC+
•
50Ω
0.1μF
Clock Duty Cycle Stabilizer
1.5V
BIAS
100Ω V
DD
8.2pF
50Ω
4.8k
ENC–
0.1μF
9003 F08
Figure 8. Transformer Driven ENC+/ENC–
ENC+
VTHRESHOLD = 1.5V
1.5V ENC–
The lower limit of the sample rate is determined by the
droop of the sample-and-hold circuits. The pipelined architecture of this ADC relies on storing analog signals on
small valued capacitors. Junction leakage will discharge
the capacitors. The specified minimum operating frequency
for the LTM9003 is 1Msps.
LTM9003
0.1μF
An optional clock duty cycle stabilizer circuit can be used if
the input clock has a non 50% duty cycle. This circuit uses
the rising edge of the ENC+ pin to sample the analog input.
The falling edge of ENC+ is ignored and the internal falling
edge is generated by a phase-locked loop. The input clock
duty cycle can vary from 40% to 60% and the clock duty
cycle stabilizer will maintain a constant 50% internal duty
cycle. If the clock is turned off for a long period of time,
the duty cycle stabilizer circuit will require one hundred
clock cycles for the PLL to lock onto the input clock. To
use the clock duty cycle stabilizer, the MODE pin should be
connected to 1/3VDD or 2/3VDD using external resistors.
9003 F09
Figure 9. Single-Ended ENC Driver, Not Recommended
for Low Jitter
0.1μF
LVDS
CLOCK
100Ω 0.1μF
ENC+
ENC–
LTM9003
9003 F10
Figure 10. ENC Drive Using LVDS
Maximum and Minimum Conversion Rates
The maximum conversion rate for the ADC is 250Msps.
For the ADC to operate properly, the encode signal should
have a 50% (±5%) duty cycle. Each half cycle must have
at least 1.9ns for the ADC internal circuitry to have enough
settling time for proper operation. Achieving a precise 50%
duty cycle is easy with differential sinusoidal drive using
a transformer or using symmetric differential logic such
as PECL or LVDS.
Clock Sources for Undersampling
Undersampling is especially demanding on the clock source
and the higher the input frequency, the greater the sensitivity
to clock jitter or phase noise. A clock source that degrades
SNR of a full-scale signal by 1dB at 70MHz will degrade
SNR by 3dB at 140MHz, and 4.5dB at 190MHz.
In cases where absolute clock frequency accuracy is
relatively unimportant and only a single ADC is required, a
canned oscillator from vendors such as Saronix or Vectron
can be placed close to the ADC and simply connected
directly to the ADC. If there is any distance to the ADC,
some source termination to reduce ringing that may occur
even over a fraction of an inch is advisable. You must not
allow the clock to overshoot the supplies or performance
will suffer. Do not filter the clock signal with a narrow band
filter unless you have a sinusoidal clock source, as the
rise and fall time artifacts present in typical digital clock
signals will be translated into phase noise.
9003p
18
LTM9003
APPLICATIONS INFORMATION
The lowest phase noise oscillators have single-ended
sinusoidal outputs, and for these devices the use of a filter
close to the ADC may be beneficial. This filter should be
close to the ADC to both reduce roundtrip reflection times,
as well as reduce the susceptibility of the traces between
the filter and the ADC. If the circuit is sensitive to closein phase noise, the power supply for oscillators and any
buffers must be very stable, or propagation delay variation
with supply will translate into phase noise. Even though
these clock sources may be regarded as digital devices, do
not operate them on a digital supply. If your clock is also
used to drive digital devices such as an FPGA, you should
locate the oscillator, and any clock fan-out devices close to
the ADC, and give the routing to the ADC precedence. The
clock signals to the FPGA should have series termination at
the driver to prevent high frequency noise from the FPGA
disturbing the substrate of the clock fan-out device. If you
use an FPGA as a programmable divider, you must re-time
the signal using the original oscillator, and the re-timing
flip-flop as well as the oscillator should be close to the
ADC, and powered with a very quiet supply.
For cases where there are multiple ADCs, or where the
clock source originates some distance away, differential
clock distribution is advisable. This is advisable both from
the perspective of EMI, but also to avoid receiving noise
from digital sources both radiated, as well as propagated in
the waveguides that exist between the layers of multilayer
PCBs. The differential pairs must be close together and
distanced from other signals. The differential pair should
be guarded on both sides with copper distanced at least
3x the distance between the traces, and grounded with
vias no more than 1/4 inch apart.
Digital Outputs
Table 3 shows the relationship between the analog input
voltage, the digital data bits, and the overflow bit.
Table 3. Output Codes vs Input Voltage
INPUT
(SENSE = VDD)
OF
D11 – D0
(OFFSET BINARY)
D11 – D0
(2’S COMPLEMENT)
Overvoltage
1
1111 1111 1111
0111 1111 1111
Maximum
0
0
1111 1111 1111
1111 1111 1110
0111 1111 1111
0111 1111 1110
0
0
0
0
1000 0000 0001
1000 0000 0000
0111 1111 1111
0111 1111 1110
0000 0000 0001
0000 0000 0000
1111 1111 1111
1111 1111 1110
Minimum
0
0
0000 0000 0001
0000 0000 0000
1000 0000 0001
1000 0000 0000
Undervoltage
1
0000 0000 0000
1000 0000 0000
0.000000V
Digital Output Buffers
Figure 11 shows an equivalent circuit for a differential
output pair in the LVDS output mode. A 3.5mA current is
steered from OUT+ to OUT– or vice versa which creates a
±350mV differential voltage across the 100Ω termination
resistor at the LVDS receiver. A feedback loop regulates
the common mode output voltage to 1.25V. For proper
operation each LVDS output pair needs an external 100Ω
LTM9003
OVDD
2.5V
0.1μF
D
D
OUT+
–
+
10k
10k
100Ω
1.25V
OUT–
LVDS
RECEIVER
D
D
3.5mA
OGND
9003 F11
Figure 11. Digital Output in LVDS Mode
9003p
19
LTM9003
APPLICATIONS INFORMATION
termination resistor, even if the signal is not used (such as
OF+/OF– or CLKOUT+/CLKOUT–). To minimize noise the PC
board traces for each LVDS output pair should be routed
close together. To minimize clock skew all LVDS PC board
traces should have about the same length.
Data Format
The LTM9003 parallel digital output can be selected for
offset binary or 2’s complement format. The format is
selected with the MODE pin. Connecting MODE to GND
or 1/3VDD selects offset binary output format. Connecting
MODE to 2/3VDD or VDD selects 2’s complement output
format. An external resistor divider can be used to set the
1/3VDD or 2/3VDD logic values. Table 5 shows the logic
states for the MODE pin.
Output Enable
The outputs may be disabled with the output enable
pin, OE. In LVDS output mode OE high disables all data
outputs including OF and CLKOUT. The data access and
bus relinquish times are too slow to allow the outputs to
be enabled and disabled during full speed operation. The
output Hi-Z state is intended for use during long periods
of inactivity.
The Hi-Z state is not a truly open circuit; the output pins
that make an LVDS output pair have a 20k resistance
between them.
Sleep and Nap Modes
An overflow output bit indicates when the converter is
overranged or underranged. A differential logic high on
the OF+/OF– pins indicates an overflow or underflow.
The converter may be placed in shutdown or nap modes
to conserve power. Connecting SHDN to GND results in
normal operation. Connecting SHDN to VDD and OE to VDD
results in sleep mode, which powers down all circuitry
including the reference and the ADC typically dissipates
1mW. When exiting sleep mode, it will take milliseconds
for the output data to become valid because the reference
capacitors have to recharge and stabilize. Connecting
SHDN to VDD and OE to GND results in nap mode and the
ADC typically dissipates 30mW. In nap mode, the on-chip
reference circuit is kept on, so that recovery from nap
mode is faster than that from sleep mode, typically taking
100 clock cycles. In both sleep and nap modes, all digital
outputs are disabled and enter the Hi-Z state.
Output Clock
Supply Sequencing
The LTM9003 has a delayed version of the ENC+ input available as a digital output, CLKOUT. The CLKOUT pin can be
used to synchronize the converter data to the digital system.
This is necessary when using a sinusoidal encode. Data
will be updated just after CLKOUT+/CLKOUT– rises and can
be latched on the falling edge of CLKOUT+/CLKOUT–.
The VCC1 and VCC2 pins provide the supply to the mixer
and amplifier, respectively, and the VDD pin provides the
supply to the ADC. The mixer, amplifier and ADC are separate integrated circuits within the LTM9003. Separate linear
regulators can be used without additional supply sequencing circuitry if they have common input supplies.
Table 5. MODE Pin Function
MODE PIN
OUTPUT FORMAT
CLOCK DUTY CYCLE
STABILIZER
0
Straight Binary
Off
1/3VDD
Straight Binary
On
2/3VDD
2’s Complement
On
VDD
2’s Complement
Off
Overflow Bit
Output Driver Power
OVDD should be connected to a 2.5V supply and OGND
should be connected to GND.
9003p
20
LTM9003
APPLICATIONS INFORMATION
Grounding and Bypassing
The LTM9003 requires a printed circuit board with a
clean unbroken ground plane; a multilayer board with an
internal ground plane is recommended. The pinout of the
LTM9003 has been optimized for a flow-through layout
so that the interaction between inputs and digital outputs
is minimized. Ample ground pads facilitate a layout that
ensures that digital and analog signal lines are separated
as much as possible.
The LTM9003 is internally bypassed with the ADC (VDD),
amplifier (VCC2) and mixer (VCC1) supplies returning to a
common ground (GND). The digital output supply (OVDD)
is returned to OGND. Additional bypass capacitance is
optional and may be required if power supply noise is
significant.
Heat Transfer
Most of the heat generated by the LTM9003 is transferred
through the bottom-side ground pads. For good electrical
and thermal performance, it is critical that all ground pins
are connected to a ground plane of sufficient area with as
many vias as possible.
Recommended Layout
The high integration of the LTM9003 makes the PCB board
layout very simple and easy. However, to optimize its electrical and thermal performance, some layout considerations
are still necessary.
• Use large PCB copper areas for ground. This helps to
dissipate heat in the package through the board and also
helps to shield sensitive on-board analog signals. Common
ground (GND) and output ground (OGND) are electrically
isolated on the LTM9003, but can be connected on the PCB
underneath the part to provide a common return path.
• Use multiple ground vias. Using as many vias as possible helps to improve the thermal performance of the
board and creates necessary barriers separating analog
and digital traces on the board at high frequencies.
• Separate analog and digital traces as much as possible,
using vias to create high-frequency barriers. This will reduce digital feedback that can reduce the signal-to-noise
ratio (SNR) and dynamic range of the LTM9003.
Figures 12 through 15 give a good example of the recommended layout.
The quality of the paste print is an important factor in
producing high yield assemblies. It is recommended to
use a type 3 or 4 printing no-clean solder paste. The solder
stencil design should follow the guidelines outlined in
Application Note 100.
The LTM9003 employs gold-finished pads for use with
Pb-based or tin-based solder paste. It is inherently Pb-free
and complies with the JEDEC (e4) standard. The materials declaration is available online at http://www.linear.
com/leadfree/mat_dec.jsp.
9003p
21
LTM9003
APPLICATIONS INFORMATION
Figure 12. Layer 1 Component Side
Figure 13. Layer 2
Figure 14. Layer 3
Figure 15. Backside
9003p
22
4
5.080
3.810
2.540
1.270
0.000
1.270
2.540
3.810
5.080
3.175
3.175
SUGGESTED PCB LAYOUT
TOP VIEW
1.905
PACKAGE TOP VIEW
0.635
0.000
0.635
PAD 1
CORNER
15
BSC
1.905
X
11.25
BSC
Y
DETAIL B
2.22 – 2.42
DETAILS OF PAD #1 IDENTIFIER ARE OPTIONAL,
BUT MUST BE LOCATED WITHIN THE ZONE INDICATED.
THE PAD #1 IDENTIFIER MAY BE EITHER A MOLD OR
MARKED FEATURE
LAND DESIGNATION PER JESD MO-222, SPP-010
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
SYMBOL TOLERANCE
0.15
aaa
0.10
bbb
0.05
eee
6. THE TOTAL NUMBER OF PADS: 108
5. PRIMARY DATUM -Z- IS SEATING PLANE
4
3
2. ALL DIMENSIONS ARE IN MILLIMETERS
1.27
BSC
10.16
BSC
3
12
TRAY PIN 1
BEVEL
COMPONENT
PIN “A1”
PADS
SEE NOTES
NOTES:
1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M-1994
DETAIL A
0.27 – 0.37
SUBSTRATE
eee S X Y
DETAIL B
0.630 ±0.025 SQ. 108x
aaa Z
1.95 – 2.05
MOLD
CAP
Z
5.715
4.445
4.445
5.715
6.985
(Reference LTC DWG # 05-08-1757 Rev Ø)
// bbb Z
aaa Z
6.985
LGA Package
108-Lead (15mm × 11.25mm × 2.32mm)
11
10
9
7
6
5
4
3
2
1
DETAIL A
A
B
C
D
E
F
G
H
J
DIA (0.635)
PAD 1
0.22 × 45°
CHAMFER
LGA 108 0707 REV Ø
PACKAGE IN TRAY LOADING ORIENTATION
LTMXXXXXX
μModule
PACKAGE BOTTOM VIEW
8
13.97
BSC
LTM9003
PACKAGE DESCRIPTION
9003p
23
LTM9003
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9003p
24 Linear Technology Corporation
LT 0709 • PRINTED IN USA
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