LTC6946 - Ultralow Noise and Spurious 0.37GHz to 6.39GHz Integer-N Synthesizer with Integrated VCO

LTC6946
Ultralow Noise and Spurious
0.37GHz to 6.39GHz Integer-N
Synthesizer with Integrated VCO
Description
Features
Low Noise Integer-N PLL with Integrated VCO
nn –226dBc/Hz Normalized In-Band Phase Noise Floor
nn –274dBc/Hz Normalized In-Band 1/f Noise
nn –157dBc/Hz Wideband Output Phase Noise Floor
nn Excellent Spurious Performance
nn Output Divider (1 to 6, 50% Duty Cycle)
nn Output Buffer Muting
nn Low Noise Reference Buffer
nn Charge Pump Current Adjustable from 250µA to
11.2mA
nn Configurable Status Output
nn SPI Compatible Serial Port Control
nn PLLWizard™ Software Design Tool Support
The LTC®6946 is a high performance, low noise, 6.39GHz
phase-locked loop (PLL) with a fully integrated VCO,
including a reference divider, phase-frequency detector
(PFD) with phase-lock indicator, ultralow noise charge
pump, integer feedback divider, and VCO output divider.
The charge pump contains selectable high and low voltage
clamps useful for VCO monitoring.
nn
The integrated low noise VCO uses no external components.
It is internally calibrated to the correct output frequency
with no external system support.
The part features a buffered, programmable VCO output
divider with a range of 1 through 6, providing a wide
frequency range.
Applications
Frequency Coverage Options
LTC6946-1
Wireless Base Stations (LTE, WiMAX, W-CDMA, PCS)
nn Broadband Wireless Access
nn Military and Secure Radio
nn Test and Measurement
nn
LTC6946-2
LTC6946-3
LTC6946-4
O DIV=1 2.240 to 3.740 3.080 to 4.910 3.840 to 5.790 4.200 to 6.390
O DIV=2 1.120 to 1.870 1.540 to 2.455 1.920 to 2.895 2.100 to 3.195
0 DIV=3
0.747 to 1.247 1.027 to 1.637 1.280 to 1.930 1.400 to 2.130
O DIV=4 0.560 to 0.935 0.770 to 1.228 0.960 to 1.448 1.050 to 1.598
O DIV=5 0.448 to 0.748 0.616 to 0.982 0.768 to 1.158 0.840 to 1.278
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks and
PLLWizard is a trademark of Linear Technology Corporation. All other trademarks are the
property of their respective owners.
O DIV=6 0.373 to 0.623 0.513 to 0.818 0.640 to 0.965 0.700 to 1.065
Typical Application
5.7GHz Wideband Receiver
LTC6946-3 PLL Phase Noise
4.7nF
TB
LTC6946-3
3.3V
GND
–
MUTE
SDO
SDI
CS
STAT
SCLK
SPI BUS
3.3V
100pF
RF
LO IF
TO IF
PROCESSING
100pF
50Ω
6946 TA01a
3.3V
0.1µF
68nH RF INPUT
SIGNAL
RF–
REF+
VREFO+
51.1Ω
0.01µF
–90
68nH
RF+
REF
1µF
10MHz
CMC
VRF+
REFO
+
3.3V
VD+
1µF
GND
BB
VCP+
VREF+
0.01µF
57nF
1µF
GND
CP
3.3V
CMB
CMA
GND
VVCO+
0.01µF
97.6Ω
2.2µF
TUNE
0.01µF
0.1µF
UNUSED OUTPUT
IS AVAILABLE
FOR OTHER USE
PHASE NOISE (dBc/Hz)
5V
15Ω
–80
0.01µF
–100
–110
–120
–130
RMS NOISE = 0.61°
–140 RMS JITTER = 296fs
fRF = 5.7GHz
–150 fPFD = 10MHz
BW = 85kHz
–160
1M
1k
100
10k
100k
OFFSET FREQUENCY (Hz)
10M 40M
6946 TA01b
6946fb
For more information www.linear.com/LTC6946
1
LTC6946
Pin Configuration
Supply Voltages
V+ (VREF+, VREFO+, VRF+, VD+) to GND...................3.6V
VCP+, V VCO+ to GND..............................................5.5V
Voltage on CP Pin..................GND – 0.3V to VCP+ + 0.3V
Voltage on All Other Pins...........GND – 0.3V to V+ + 0.3V
Operating Junction Temperature Range, TJ (Note 2)
LTC6946I................................................ –40°C to 105°C
Junction Temperature, TJMAX................................. 125°C
Storage Temperature Range................... –65°C to 150°C
GND
VCP+
CP
REF–
TOP VIEW
VREF+
(Note 1)
REF+
Absolute Maximum Ratings
28 27 26 25 24 23
22 VVCO+
VREFO+ 1
REFO 2
21 GND
STAT 3
20 CMA
CS 4
19 CMB
29
GND
SCLK 5
18 CMC
SDI 6
17 GND
SDO 7
16 TB
VD+ 8
15 TUNE
BB
VRF+
RF+
RF
–
GND
MUTE
9 10 11 12 13 14
UFD PACKAGE
28-LEAD (4mm × 5mm) PLASTIC QFN
TJMAX = 125°C, θJCbottom = 3°C/W, θJCtop = 26°C/W
EXPOSED PAD (PIN 29) IS GND, MUST BE SOLDERED TO PCB
Order Information
LEAD FREE FINISH
TAPE AND REEL
PART MARKING
PACKAGE DESCRIPTION
JUNCTION TEMPERATURE RANGE
LTC6946IUFD-1#PBF
LTC6946IUFD-1#TRPBF
69461
28-Lead (4mm × 5mm) Plastic QFN
–40°C to 105°C
LTC6946IUFD-2#PBF
LTC6946IUFD-2#TRPBF
69462
28-Lead (4mm × 5mm) Plastic QFN
–40°C to 105°C
LTC6946IUFD-3#PBF
LTC6946IUFD-3#TRPBF
69463
28-Lead (4mm × 5mm) Plastic QFN
–40°C to 105°C
LTC6946IUFD-4#PBF
LTC6946IUFD-4#TRPBF
69464
28-Lead (4mm × 5mm) Plastic QFN
–40°C to 105°C
Consult LTC Marketing for parts specified with wider operating temperature ranges.
Consult LTC Marketing for information on non-standard lead based finish parts.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
Available Options
VCO FREQUENCY
RANGE (GHz)
PACKAGE STYLE
QFN-28 (UFD28)
OUTPUT FREQUENCY RANGE vs OUTPUT DIVIDER SETTING (GHz)
0 DIV = 6
0 DIV = 5
0 DIV = 4
0 DIV = 3
0 DIV = 2
0 DIV = 1
2.240 to 3.740
LTC6946IUFD-1
0.373 to 0.623
0.448 to 0.748
0.560 to 0.935
0.747 to 1.247
1.120 to 1.870
2.240 to 3.740
3.080 to 4.910
LTC6946IUFD-2
0.513 to 0.818
0.616 to 0.982
0.770 to 1.228
1.027 to 1.637
1.540 to 2.455
3.080 to 4.910
3.840 to 5.790
LTC6946IUFD-3
0.640 to 0.965
0.768 to 1.158
0.960 to 1.448
1.280 to 1.930
1.920 to 2.895
3.840 to 5.790
4.200 to 6.390
LTC6946IUFD-4
0.700 to 1.065
0.840 to 1.278
1.050 to 1.598
1.400 to 2.130
2.100 to 3.195
4.200 to 6.390
Overlapping Frequency Bands
2
6946fb
For more information www.linear.com/LTC6946
LTC6946
Electrical
Characteristics
The l denotes the specifications which apply over the full operating
junction temperature range, otherwise specifications are at TA = 25°C. VREF+ = VREF0+ = VD+ = VRF+ = 3.3V, VCP+ = VVCO+ = 5V unless
otherwise specified (Note 2). All voltages are with respect to GND.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
250
MHz
Reference Inputs (REF+, REF–)
fREF
Input Frequency
VREF
Input Signal Level
Single Ended, 1µF AC-Coupling Capacitors
Input Slew Rate
l
10
l
0.5
l
20
Input Duty Cycle
2
2.7
50
Self-Bias Voltage
Input Resistance
Differential
Input Capacitance
Differential
VP-P
V/µs
%
l
1.65
1.85
2.25
V
l
6.2
8.4
11.6
kΩ
3
pF
Reference Output (REFO)
fREFO
Output Frequency
PREFO
Output Power
fREFO = 10MHz, RLOAD = 50Ω
l
10
250
MHz
l
–0.2
3.2
dBm
Output Impedance, Disabled
800
Ω
VCO
fVCO
Frequency Range
LTC6946-1 (Note 3)
LTC6946-2 (Note 3)
LTC6946-3 (Note 3)
LTC6946-4 (Note 3)
KVCO
Tuning Sensitivity
LTC6946-1 (Notes 3, 4)
LTC6946-2 (Notes 3, 4)
LTC6946-3 (Notes 3, 4)
LTC6946-4 (Notes 3, 4)
l
l
l
l
2.24
3.08
3.84
4.20
3.74
4.91
5.79
6.39
4.7 to 7.2
4.7 to 7.0
4.0 to 6.0
4.5 to 6.5
GHz
GHz
GHz
GHz
%Hz/V
%Hz/V
%Hz/V
%Hz/V
RF Output (RF+, RF–)
fRF
O
Output Frequency
Output Divider Range
All Integers Included
l
0.373
l
1
Output Duty Cycle
Output Resistance
+
Single Ended, Each Output to VRF
GHz
6
50
Output Common Mode Voltage
PRF(SE)
6.39
136
%
l
111
159
Ω
l
2.4
VRF+
V
–9.7
–6.8
–3.9
–1.2
–6.0
–3.6
–0.4
2.3
dBm
dBm
dBm
dBm
Output Power, Single Ended,
fRF = 900MHz
RFO[1:0] = 0, RZ = 50Ω, LC Match
RFO[1:0] = 1, RZ = 50Ω, LC Match
RFO[1:0] = 2, RZ = 50Ω, LC Match
RFO[1:0] = 3, RZ = 50Ω, LC Match
l
l
l
l
Output Power, Muted
RZ = 50Ω, Single Ended, fRF = 900MHz,
O = 2 to 6
l
–60
dBm
Mute Enable Time
l
110
ns
Mute Disable Time
l
170
ns
l
100
MHz
Phase/Frequency Detector
fPFD
Input Frequency
Lock Indicator, Available on the STAT Pin and via the SPI-Accessible Status Register
tLWW
Lock Window Width
LKWIN[1:0] = 0
LKWIN[1:0] = 1
LKWIN[1:0] = 2
LKWIN[1:0] = 3
tLWHYS
Lock Window Hysteresis
Increase in tLWW Moving from Locked State to
Unlocked State
3.0
10.0
30.0
90.0
ns
ns
ns
ns
22
%
6946fb
For more information www.linear.com/LTC6946
3
LTC6946
Electrical
Characteristics
The l denotes the specifications which apply over the full operating
junction temperature range, otherwise specifications are at TA = 25°C. VREF+ = VREF0+ = VD+ = VRF+ = 3.3V, VCP+ = VVCO+ = 5V unless
otherwise specified (Note 2). All voltages are with respect to GND.
SYMBOL
PARAMETER
CONDITIONS
MIN
Output Current Range
12 Settings (See Table 5)
TYP
MAX
UNITS
11.2
mA
±6
%
±3.5
±2
%
%
Charge Pump
ICP
0.25
+/2
Output Current Source/Sink Accuracy
All Settings VCP = VCP
Output Current Source/Sink Matching
ICP = 250µA to 1.4mA, VCP = VCP+/2
ICP = 2.0mA to 11.2mA, VCP = VCP+/2
Output Current vs Output Voltage Sensitivity (Note 5)
VCLMP(LO)
+/2
l
0.1
l
170
1.0
ppm/°C
%/V
Output Current vs Temperature
VCP = VCP
Output Hi-Z Leakage Current
ICP = 700µA, CPCLO = CPCHI = 0 (Note 5)
ICP = 11.2mA, CPCLO = CPCHI = 0 (Note 5)
0.5
5
nA
nA
Low Clamp Voltage
CPCLO = 1
0.84
V
+
VCLMP(HI)
High Clamp Voltage
CPCHI = 1, Referred to VCP
–0.96
V
VMID
Mid-Supply Output Bias Ratio
Referred to (VCP+ – GND)
0.48
V/V
Reference (R) Divider
R
Divide Range
All Integers Included
l
1
1023
counts
All Integers Included
l
32
65535
counts
1.55
VCO (N) Divider
N
Divide Range
Digital Pin Specifications
VIH
High Level Input Voltage
MUTE, CS, SDI, SCLK
l
VIL
Low Level Input Voltage
MUTE, CS, SDI, SCLK
l
VIHYS
Input Voltage Hysteresis
MUTE, CS, SDI, SCLK
250
Input Current
MUTE, CS, SDI, SCLK
l
IOH
High Level Output Current
SDO and STAT, VOH = VD+ – 400mV
l
IOL
Low Level Output Current
SDO and STAT, VOL = 400mV
l
SDO Hi-Z Current
V
0.8
–2.3
1.8
mV
±1
µA
– 1.4
mA
2.6
mA
±1
l
V
µA
Digital Timing Specifications (See Figures 7 and 8)
tCKH
SCLK High Time
l
25
ns
tCKL
SCLK Low Time
l
25
ns
tCSS
CS Setup Time
l
10
ns
tCSH
CS High Time
l
10
ns
tCS
SDI to SCLK Setup Time
l
6
ns
tCH
SDI to SCLK Hold Time
l
6
tDO
SCLK to SDO Time
To VIH/VIL/Hi-Z with 30pF Load
ns
l
16
ns
Power Supply Voltages
VREF+ Supply Range
l
3.15
3.3
3.45
V
VREFO+ Supply Range
l
3.15
3.3
3.45
V
+ Supply Range
l
3.15
3.3
3.45
V
VRF
l
3.15
3.3
3.45
V
VVCO+ Supply Range
l
4.75
5.0
5.25
V
l
4.0
5.25
V
VD
+ Supply Range
VCP
4
+ Supply Range
6946fb
For more information www.linear.com/LTC6946
LTC6946
Electrical
Characteristics
The l denotes the specifications which apply over the full operating
junction temperature range, otherwise specifications are at TA = 25°C. VREF+ = VREF0+ = VD+ = VRF+ = 3.3V, VCP+ = VVCO+ = 5V unless
otherwise specified (Note 2). All voltages are with respect to GND.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
500
µA
Power Supply Currents
IDD
VD+ Supply Current
+, V
+ Supply Currents
Digital Inputs at Supply Levels
l
ICP = 11.2mA
ICP = 1.0mA
PDALL = 1
l
l
l
50
28
405
63
39
660
mA
mA
µA
ICC(5V)
Sum VCP
ICC(REFO)
VREFO+ Supply Currents
REFO Enabled, RZ = ∞
l
7.8
9.0
mA
ICC (3.3V)
Sum VREF+, VRF+ Supply Currents
RF Muted, OD[2:0] = 1
RF Enabled, RFO[1:0] =0, OD[2:0] = 1
RF Enabled, RFO[1:0] = 3, OD[2:0] = 1
RF Enabled, RFO[1:0] =3, OD[2:0] = 2
RF Enabled, RFO[1:0] =3, OD[2:0] = 3
RF Enabled, RFO[1:0] =3, OD[2:0] = 4 to 6
PDALL = 1
l
l
l
l
l
l
l
65
76
85
103
108
113
195
76
86
97
117
123
128
340
mA
mA
mA
mA
mA
mA
µA
VCO
Phase Noise and Spurious
LM
LM(NORM)
Phase Noise (LTC6946-1, fVCO = 3.0GHz, fRF 10kHz Offset
= 3.0GHz, OD[2 :0] = 1 (Note 6))
1MHz Offset
40MHz Offset
–80
–130
–157
dBc/Hz
dBc/Hz
dBc/Hz
Phase Noise (LTC6946-2, fVCO = 4.0GHz, fRF 10kHz Offset
= 4.0GHz, OD[2 :0] = 1 (Note 6))
1MHz Offset
40MHz Offset
–77
–127
–156
dBc/Hz
dBc/Hz
dBc/Hz
Phase Noise (LTC6946-3, fVCO = 5.0GHz, fRF 10kHz Offset
= 5.0GHz, OD[2 :0] = 1 (Note 6))
1MHz Offset
40MHz Offset
–75
–126
–155
dBc/Hz
dBc/Hz
dBc/Hz
VCO Phase Noise (LTC6946-4, fVCO =
10kHz Offset
6.0GHz, fRF = 6.0GHz, OD[2 :0] = 1 (Note 6)) 1MHz Offset
40MHz Offset
–73
–132
–154
dBc/Hz
dBc/Hz
dBc/Hz
Phase Noise (LTC6946-3, fVCO = 5.0GHz, fRF 10kHz Offset
= 2.50GHz, OD[2 :0] = 2 (Note 6))
1MHz Offset
40MHz Offset
–81
–132
–155
dBc/Hz
dBc/Hz
dBc/Hz
Phase Noise (LTC6946-3, fVCO = 5.0GHz, fRF 10kHz Offset
= 1.667GHz, OD[2 :0] = 3 (Note 6))
1MHz Offset
40MHz Offset
–84
–135
–156
dBc/Hz
dBc/Hz
dBc/Hz
Phase Noise (LTC6946-3, fVCO = 5.0GHz, fRF 10kHz Offset
= 1.25GHz, OD[2 :0] = 4 (Note 6))
1MHz Offset
40MHz Offset
–87
–138
–156
dBc/Hz
dBc/Hz
dBc/Hz
Phase Noise (LTC6946-3, fVCO = 5.0GHz, fRF 10kHz Offset
= 1.00GHz, OD[2 :0] = 5 (Note 6))
1MHz Offset
40MHz Offset
–89
–140
–157
dBc/Hz
dBc/Hz
dBc/Hz
Phase Noise (LTC6946-3, fVCO = 5.0GHz, fRF 10kHz Offset
= 0.833GHz, OD[2 :0] = 6 (Note 6))
1MHz Offset
40MHz Offset
–90
–141
–158
dBc/Hz
dBc/Hz
dBc/Hz
Normalized In-Band Phase Noise Floor
ICP = 11.2mA (Notes 7, 8, 9)
–226
dBc/Hz
ICP = 11.2mA (Notes 7, 10)
–274
dBc/Hz
In-Band Phase Noise Floor
(Notes 7, 8, 9, 11)
–99
dBc/Hz
Integrated Phase Noise from
100Hz to 40MHz
(Notes 8, 12)
0.17
°RMS
Spurious
fOFFSET = fPFD, PLL Locked (Notes 8, 12, 13)
–103
dBc
LM(NORM – 1/f) Normalized In-Band 1/f Phase Noise
LM(IB)
6946fb
For more information www.linear.com/LTC6946
5
LTC6946
Electrical Characteristics
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: The LTC6946I is guaranteed to meet specified performance limits
over the full operating junction temperature range of –40°C to 105°C.
Under maximum operating conditions, air flow or heat sinking may
be required to maintain a junction temperature of 105°C or lower. It is
strongly recommended that the exposed pad (Pin 29) be soldered directly
to the ground plane with an array of thermal vias as described in the
Applications Information section.
Note 3: Valid for 1.60V ≤ TUNE ≤ 2.85V with part calibrated after a power
cycle or software power-on-reset (POR).
Note 4: Based on characterization.
Note 5: For 0.9V ≤ VCP ≤ (VCP+ – 0.9V).
Note 6: Measured outside the loop bandwidth, using a narrowband loop,
RFO[1:0] = 3.
6
Note 7: Measured inside the loop bandwidth with the loop locked.
Note 8: Reference frequency supplied by Wenzel 501-04608A,
fREF = 10MHz, PREF = 13dBm.
Note 9: Output phase noise floor is calculated from normalized phase
noise floor by LM(OUT) = –226 + 10log10 (fPFD) + 20log10 (fRF/fPFD).
Note 10: Output 1/f phase noise is calculated from normalized 1/f phase
noise by LM(OUT – 1/f) = –274 + 20log10 (fRF) – 10log10 (fOFFSET).
Note 11: ICP = 11.2mA, fPFD = 250kHz, FILT[1:0] = 3, Loop BW = 25kHz;
fRF = 900MHz, fVCO = 2.7GHz (LTC6946-1), fVCO = 3.6GHz (LTC6946-2),
fVCO = 4.5GHz (LTC6946-3, LTC6946-4).
Note 12: ICP = 11.2mA, fPFD = 1MHz, FILT[1:0] = 3, Loop BW = 40kHz;
fRF = 900MHz, fVCO = 2.7GHz (LTC6946-1), fVCO = 3.6GHz (LTC6946-2),
fVCO = 4.5GHz (LTC6946-3, LTC6946-4).
Note 13: Measured using DC1705.
6946fb
For more information www.linear.com/LTC6946
LTC6946
Typical +Performance
Characteristics
+
+
+
+
+
TA = 25°C, VREF = VREFO = VD = VRF = 3.3V, VCP = VVCO = 5V, RFO[1:0] = 3,unless otherwise noted.
REF Input Sensitivity
vs Frequency
BST = 1
FILT = 0
TJ = 105°C
TJ = 25°C
TJ = –40°C
–20
–25
–30
–35
–40
2
–45
1
0
–1
–2
–50
–55
TJ = 105°C
TJ = 25°C
TJ = –40°C
–3
0
–4
25 50 75 100 125 150 175 200 225 250
FREQUENCY (MHz)
0
25 50 75 100 125 150 175 200 225 250
FREQUENCY (MHz)
6946 G01
–150
–155
–160
100
Charge Pump Source Current
Error vs Voltage, Output Current
5
4
4
4
3
3
3
2
2
2
1
1
1
0
–1
–2
–2
–3
–3
250µA
1mA
11.2mA
–5
0
0.5
1
1.5 2 2.5 3 3.5 4
OUTPUT VOLTAGE (V)
4.5
–4
–5
5
0
0.5
1
1.5 2 2.5 3 3.5 4
OUTPUT VOLTAGE (V)
–3
Charge Pump Source Current
Error vs Voltage, Temperature
–5
5
5
1.5
4
1.0
3
0.5
2
POUT (dBm)
–1
–2
–20
–25
–1.0
–1.5
–2.0
–3.0
–3.5
5
6946 G07
–30
–0.5
–2.5
4.5
0.5
1
1.5 2 2.5 3 3.5 4
OUTPUT VOLTAGE (V)
–4.0
LTC6946-3
LC = 68nH
CS = 100pF
TJ = 105°C
TJ = 25°C
TJ = –40°C
4.5
5
RF Output HD2 vs Output Divide
(Single Ended on RF–)
0
0
0
6946 G06
RF Output Power vs Frequency
(Single Ended on RF–)
1
250µA
1mA
11.2mA
–4
6946 G05
6946 G04
ICP = 11.2mA
–3
TJ = 105°C
TJ = 25°C
–4
TJ = –40°C
–5
0 0.5 1 1.5 2 2.5 3 3.5 4
OUTPUT VOLTAGE (V)
4.5
0
–1
–2
ICP = 11.2mA
TJ = 105°C
TJ = 25°C
TJ = –40°C
HD2 (dBc)
–4
ERROR (%)
5
0
10k
100k
1M
1k
OFFSET FREQUENCY (Hz)
6946 G03
5
ERROR (%)
ERROR (%)
–145
Charge Pump Sink Current Error
vs Voltage, Temperature
–1
POUT = 1.45dBm
fREF = 10MHz
BST = 1
FILT = 3
NOTE 8
6946 G02
Charge Pump Sink Current Error
vs Voltage, Output Current
ERROR (%)
REFO Phase Noise
–140
3
POUT (dBm)
SENSITIVITY (dBm)
REF0 Output Power vs Frequency
4
PHASE NOISE (dBc/Hz)
–15
–35
LTC6946-3, fRF = fVCO/O
LC = 68nH, CS = 100pF
O=3
O=2
O=5
O=1
O=6
–40
–45
0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 6
FREQUENCY (GHz)
6946 G08
O=4
–50
3.75 4.00 4.25 4.50 4.75 5.00 5.25 5.50 5.75
fVCO (GHz)
6946 G09
6946fb
For more information www.linear.com/LTC6946
7
LTC6946
Typical +Performance
Characteristics
+
+
+
+
+
TA = 25°C, VREF = VREFO = VD = VRF = 3.3V, VCP = VVCO = 5V, RFO[1:0] = 3,unless otherwise noted.
RF Output HD3 vs Output Divide
(Single Ended on RF–)
MUTE Output Power vs fVCO and
Output Divide (Single Ended on RF–)
–10
O=5
O=6
O=3
HD3 (dBc)
–15
O=2
–20
–25
–30
–35
O=1
LTC6946-3
LC = 68nH
CS = 100pF
fRF = fVCO/O
POUT AT fVCO/O (dBm)
O=4
–50
LTC6946-3, LC = 68nH
CS = 100pF, fRF = fVCO/O
–60
O=1
–70
O=2
–80
O=3
5.9
O=4
–90 O = 5
O=6
–100
LTC6946-1 VCO Tuning Sensitivity
5.1
4.5
LTC6946-2 VCO Tuning Sensitivity
7.5
6.5
7.0
7.0
6.0
6.5
6.5
5.5
6.0
5.5
5.0
4.5
4.5
4.0
4.0
3.5
3.5
3.0
2100
LTC6946-4 VCO Tuning Sensitivity
7.0
–50
3300
3800
4300
4800
FREQUENCY (MHz)
4.0
3.5
3.0
4200
4600
5000 5400 5800
FREQUENCY (MHz)
6200
6600
6946 G16
4.0
4000
4500 5000 5500
FREQUENCY (MHz)
6000
6946 G15
–40
fVCO = fRF = 3GHz
–60
–70
–70
–80
–90
–100
–110
–120
–130
–80
–90
–100
–110
–120
–130
–140
–140
–150
–150
1k
10k
100k
1M
10M 40M
OFFSET FREQUENCY (Hz)
fVCO = fRF = 4GHz
–50
–60
–160
6500
LTC6946-2 VCO Phase Noise
6946 G17
8
35
4.5
2.5
3500
5300
PHASE NOISE (dBc/Hz)
PHASE NOISE (dBc/Hz)
6.5
4.5
30
5.0
LTC6946-1 VCO Phase Noise
–40
5.0
25
6946 G14
7.5
5.5
10 15 20
TIME (µs)
3.0
6946 G13
6.0
5
3.5
3.0
2800
4100
3100
2600
3600
FREQUENCY (MHz)
KVCO (%Hz/V)
7.5
5.0
0
LTC6946-3 VCO Tuning Sensitivity
7.0
5.5
–5
6946 G12
8.0
6.0
240MHz STEP
fPFD=10MHz
fCAL=1.25MHz
BW=123kHz
MTCAL = 0
CPCHI, CPCLO = 1
4.9
8.0
KVCO (%Hz/V)
KVCO (%Hz/V)
5.3
6946 G11
6946 G10
KVCO (%Hz/V)
5.5
4.7
–110
3800 4050 4300 4550 4800 5050 5300 5550 5800
fVCO (MHz)
–40
3.75 4.00 4.25 4.50 4.75 5.00 5.25 5.50 5.75
fVCO (GHz)
CALIBRATION
TIME
5.7
FREQUENCY (GHz)
–40
–5
LTC6946-4 Frequency Step
Transient
–160
1k
10k
100k
1M
10M 40M
OFFSET FREQUENCY (Hz)
6946 G18
6946fb
For more information www.linear.com/LTC6946
LTC6946
Typical +Performance
Characteristics
+
+
+
+
+
TA = 25°C, VREF = VREFO = VD = VRF = 3.3V, VCP = VVCO = 5V, RFO[1:0] = 3,unless otherwise noted.
LTC6946-3 VCO Phase Noise
–60
–60
–70
–70
–80
–90
–100
–110
–120
–130
–90
–100
–110
–120
–130
–140
–150
–150
–160
10k
100k
1M
10M 40M
OFFSET FREQUENCY (Hz)
1k
–160
LTC6946-1 VCO Phase Noise vs fVCO,
Output Divide (fOFFSET = 10kHz)
fRF = fVCO/O
O=1
–80
–80
–140
–75
fVCO = fRF = 6GHz
–50
PHASE NOISE (dBc / Hz)
PHASE NOISE (dBc/Hz)
–40
fVCO = fRF = 5GHz
–50
PHASE NOISE (dBc/Hz)
–40
LTC6946-4 VCO Phase Noise
O=2
–85
O=3
–90
–95
O=4
O=5
O=6
2700 2950 3200
fVCO (MHz)
3450
–100
1k
–105
2200
10k
100k
1M
10M 40M
OFFSET FREQUENCY (Hz)
2450
6946 G20
6946 G19
6946 G21
LTC6946-2 VCO Phase Noise vs
fVCO, Output Divide (fOFFSET = 10kHz)
–75
O=1
–80
O=2
O=3
–85
–90
O=4
O=5
–85
O=2
O=3
O=4
O=6
PHASE NOISE (dBc/Hz)
PHASE NOISE (dBc/Hz)
–135
O=3
–140
–150
2200
–140
O=4
–145
O=5
2450
LTC6946-2 VCO Phase Noise vs
fVCO, Output Divide (fOFFSET = 1MHz)
–130
O=2
2700 2950 3200
fVCO (MHz)
O=1
O=5
O=3
O=4
O=5
O=6
–120
4600
O=6
5000 5400 5800
fVCO (MHz)
6200
6600
6946 G24
LTC6946-3 VCO Phase Noise vs fVCO,
Output Divide (fOFFSET = 1MHz)
fRF = fVCO/O
3450
fRF = fVCO /O
–150
3000 3250 3500 3750 4000 4250 4500 4750
fVCO (MHz)
6946 G26
O=1
–130
–135
–140
–145
6946 G25
–95
4200
–125
O=2
O=6
3700
O=4
O=3
O=5
–125
O=1
–135
–85
6946 G23
LTC6946-1 VCO Phase Noise vs
fVCO, Output Divide (fOFFSET = 1MHz)
–130
–80
–95
3800 4050 4300 4550 4800 5050 5300 5550 5800
fVCO (MHz)
6946 G22
fRF = fVCO/O
O=1
–90
O=6
–125
fRF = fVCO/O
O=2
–90
–100
3000 3250 3500 3750 4000 4250 4500 4750
fVCO (MHz)
LTC6946-4 VCO Phase Noise vs
fVCO, Output Divide (fOFFSET = 10kHz)
–75
O=1
PHASE NOISE (dBc/Hz)
–95
–80
–70
fRF = fVCO/O
PHASE NOISE (dBc/Hz)
–70
fRF = fVCO/O
–75
PHASE NOISE (dBc/Hz)
LTC6946-3 VCO Phase Noise vs
fVCO, Output Divide (fOFFSET = 10kHz)
PHASE NOISE (dBc/Hz)
–70
3700
O=2
O=3
O=4
O=5
O=6
–145
3800 4050 4300 4550 4800 5050 5300 5550 5800
fVCO (MHz)
6946 G27
6946fb
For more information www.linear.com/LTC6946
9
LTC6946
Typical +Performance
Characteristics
+
+
+
+
+
TA = 25°C, VREF = VREFO = VD = VRF = 3.3V, VCP = VVCO = 5V, RFO[1:0] = 3,unless otherwise noted.
fRF = fVCO/O
Closed-Loop Phase Noise, Loop
Bandwidth = 40kHz, LTC6946-1
O=1
PHASE NOISE (dBc/Hz)
PHASE NOISE (dBc/Hz)
–125
O=2
–130
O=4
–135
–140
–145
4200
O=3
O=6
O=5
–90
–90
–100
–100
–110
–120
–130
–140
–150
4600
5000 5400 5800
fVCO (MHz)
6200
RMS NOISE = 0.169°
fRF = 900MHz
fPFD = 1MHz
OD = 3
fSTEP = 333.3kHz
NOTE 12
–160
100
6600
1k
1M
10k
100k
OFFSET FREQUENCY (Hz)
6946 G28
87
54
51
85
50
84
49
83
48
82
47
81
46
0
–20
53
52
86
–20
0
55
PDREFO = 1
O=1
RFO = 3
MUTE = 0
ICP = 11.2mA
80
–40
20
40
TJ (°C)
–130
–140
RMS NOISE = 0.276°
fRF = 900MHz
fPFD = 250kHz
OD = 5
fSTEP = 50kHz
NOTE 11
–160
100
10M 40M
1k
60
6946 G30
80
100
45
RBW = 1Hz
VBW = 1Hz
NOTES 8, 13
–60
–80
–100
–105dBc
–103dBc
–111dBc
–109dBc
–120
–140
–10 –3 –2 –1 0
1
2
3 10
FREQUENCY OFFSET (MHz IN 10kHz SEGMENTS)
6946 G32
6946 G31
–20
LTC6946-3 Spurious Response
fRF = 5700MHz, fREF = 100MHz,
fPFD = 1MHz, Loop BW = 33kHz
0
RBW = 1Hz
VBW = 1Hz
NOTES 8, 13
–20
RBW = 1Hz
VBW = 1Hz
NOTE 13
–40
–60
–80
–93dBc
–86dBc
–88dBc
–94dBc
POUT (dBm)
POUT (dBm)
–40
–60
–80
–100
–100
–120
–120
–140
–10 –1.2 –0.8 –0.4 0 0.4 0.8 1.2 10
FREQUENCY OFFSET (MHz IN 10kHz SEGMENTS)
–140
–101dBc
–96dBc
–92dBc
–113dBc
–100 –3 –2 –1 0
1
2
3 100
FREQUENCY OFFSET (MHz IN 10kHz SEGMENTS)
6946 G33
10
10M 40M
–40
LTC6946-3 Spurious Response
fRF = 2200MHz, fREF = 10MHz,
fPFD = 0.4MHz, Loop BW = 28kHz
0
1M
10k
100k
OFFSET FREQUENCY (Hz)
LTC6946-3 Spurious Response
fRF = 900MHz, fREF = 10MHz,
fPFD = 1MHz, Loop BW = 40kHz
5V CURRENT (mA)
3.3V CURRENT (mA)
88
–120
6946 G29
POUT (dBm)
89
–110
–150
LTC6946-2 Supply Current
vs Temperature
90
Closed-Loop Phase Noise, Loop
Bandwidth = 25kHz, LTC6946-3
PHASE NOISE (dBc/Hz)
–120
LTC6946-4 VCO Phase Noise vs
fVCO, Output Divide (fOFFSET = 1MHz)
6946 G34
6946fb
For more information www.linear.com/LTC6946
LTC6946
Pin Functions
VREFO+ (Pin 1): 3.15V to 3.45V Positive Supply Pin for
REFO Circuitry. This pin should be bypassed directly to
the ground plane using a 0.1µF ceramic capacitor as close
to the pin as possible.
REFO (Pin 2): Reference Frequency Output. This produces
a low noise square wave, buffered from the REF± differential
inputs. The output is self-biased and must be AC-coupled
with a 22nF capacitor.
STAT (Pin 3): Status Output. This signal is a configurable
logical OR combination of the UNLOCK, LOCK, ALCHI,
ALCLO, THI and TLO status bits, programmable via the
STATUS register. See the Operation section for more details.
CS (Pin 4): Serial Port Chip Select. This CMOS input initiates a serial port communication burst when driven low,
ending the burst when driven back high. See the Operation
section for more details.
SCLK (Pin 5): Serial Port Clock. This CMOS input clocks
serial port input data on its rising edge. See the Operation
section for more details.
SDI (Pin 6): Serial Port Data Input. The serial port uses
this CMOS input for data. See the Operation section for
more details.
SDO (Pin 7): Serial Port Data Output. This CMOS threestate output presents data from the serial port during a
read communication burst. Optionally attach a resistor
of >200k to GND to prevent a floating output. See the
Operation section for more details.
VD+ (Pin 8): 3.15V to 3.45V Positive Supply Pin for Serial
Port Circuitry. This pin should be bypassed directly to the
ground plane using a 0.1µF ceramic capacitor as close to
the pin as possible.
MUTE (Pin 9): RF Mute. The CMOS active-low input mutes
the RF± differential outputs while maintaining internal bias
levels for quick response to de-assertion.
GND (Pins 10, 17, 21): Negative Power Supply (Ground).
These pins should be tied directly to the ground plane with
multiple vias for each pin.
RF–, RF+ (Pins 11, 12): RF Output Signals. The VCO
output divider is buffered and presented differentially on
these pins. The outputs are open collector, with 136Ω
(typical) pull-up resistors tied to VRF+ to aid impedance
matching. If used single ended, the unused output should
be terminated to 50Ω. See the Applications Information
section for more details on impedance matching.
VRF+ (Pin 13): 3.15V to 3.45V Positive Supply Pin for
RF Circuitry. This pin should be bypassed directly to the
ground plane using a 0.01µF ceramic capacitor as close
to the pin as possible.
BB (Pin 14): RF Reference Bypass. This output must be
bypassed with a 1.0µF ceramic capacitor to GND. Do not
couple this pin to any other signal.
TUNE (Pin 15): VCO Tuning Input. This frequency control
pin is normally connected to the external loop filter. See
the Applications Information section for more details.
TB (Pin 16): VCO Bypass. This output must be bypassed
with a 2.2µF ceramic capacitor to GND, and is normally
connected to CMA, CMB and CMC with a short trace. Do
not couple this pin to any other signal.
CMC, CMB, CMA (Pins 18, 19, 20): VCO Bias Inputs. These
inputs are normally connected to TB with a short trace
and bypassed with a 2.2µF ceramic capacitor to GND. Do
not couple these pins to any other signal. For best phase
noise performance, do not place a trace between these
pads underneath the package.
VVCO+ (Pin 22): 4.75V to 5.25V Positive Supply Pin for
VCO Circuitry. This pin should be bypassed directly to the
ground plane using both 0.01µF and 1µF ceramic capacitors as close to the pin as possible.
6946fb
For more information www.linear.com/LTC6946
11
LTC6946
Pin Functions
GND (23): Negative Power Supply (Ground). This pin is
attached directly to the die attach paddle (DAP) and should
be tied directly to the ground plane.
VCP+ (Pin 24): 4.0V to 5.25V Positive Supply Pin for Charge
Pump Circuitry. This pin should be bypassed directly to
the ground plane using a 0.1µF ceramic capacitor as close
to the pin as possible.
CP (Pin 25): Charge Pump Output. This bi-directional current output is normally connected to the external loop filter.
See the Applications Information section for more details.
VREF+ (Pin 26): 3.15V to 3.45V Positive Supply Pin for
Reference Input Circuitry. This pin should be bypassed
directly to the ground plane using a 0.1µF ceramic capacitor as close to the pin as possible.
12
REF+, REF– (Pins 27, 28): Reference Input Signals. This
differential input is buffered with a low noise amplifier,
which feeds the reference divider and reference buffer.
They are self-biased and must be AC-coupled with 1µF
capacitors. If used single ended, bypass REF– to GND
with a 1µF capacitor. If the single-ended signal is greater
than 2.7VP-P, bypass REF– to GND with a 47pF capacitor.
GND (Exposed Pad Pin 29): Negative Power Supply
(Ground). The package exposed pad must be soldered
directly to the PCB land. The PCB land pattern should
have multiple thermal vias to the ground plane for both
low ground inductance and also low thermal resistance.
6946fb
For more information www.linear.com/LTC6946
LTC6946
Block Diagram
28
27
REF–
1
2
26
REF+
24
VREF+
23
VCP+
GND
VREFO+
REFO
≤250MHz
≤100MHz
R_DIV
250µA TO
11.2mA
PFD
÷1 TO 1023
4
5
6
7
8
GND 21
STAT
B_DIV
CMA 20
CS
÷32 TO 65535
SCLK
SERIAL
PORT
N_DIV
SDI
0.373GHz TO
6.39GHz
SDO
VD+
9
GND
10
CMB 19
CAL, ALC
CONTROL
CMC 18
GND 17
÷1 TO 6, 50%
TUNE
O_DIV
15
2.24GHz TO 3.74GHz (LTC6946-1) OR
3.08GHz TO 4.91GHz (LTC6946-2) OR
3.84GHz TO 5.79GHz (LTC6946-3) OR
4.20GHz TO 6.39GHz (LTC6946-4)
MUTE
MUTE
25
VVCO+ 22
LOCK
3
CP
RF– RF+ VRF+
11
12
13
BB
TB
14
16
6946 BD
6946fb
For more information www.linear.com/LTC6946
13
LTC6946
Operation
The LTC6946 is a high performance PLL complete with
a low noise VCO available in three different frequency
range options. The output frequency range may be further
extended by utilizing the output divider (see Available Options table, for more details). The device is able to achieve
superior integrated phase noise by the combination of
its extremely low in-band phase noise performance and
excellent VCO noise characteristics.
REFERENCE INPUT BUFFER
The PLL’s reference frequency is applied differentially on
pins REF+ and REF–. These high impedance inputs are
self-biased and must be AC-coupled with 1µF capacitors
(see Figure 1 for a simplified schematic). Alternatively, the
inputs may be used single ended by applying the reference frequency at REF+ and bypassing REF– to GND with
a 1µF capacitor. If the single-ended signal is greater than
2.7VP-P, then use a 47pF capacitor for the GND bypass.
VREF+
VREF+
BIAS
LOWPASS
1.9V
27
REF+
4.2k
4.2k
FILT[1:0]
28
REF –
6946 F01
The BST bit should be set based upon the input signal level
to prevent the reference input buffer from saturating. See
Table 2 for recommended settings and the Applications
Information section for programming examples.
Table 1. FILT[1:0] Programming
FILT[1:0]
fREF
3
<20MHz
2
NA
1
20MHz to 50MHz
0
>50MHz
Table 2. BST Programming
BST
VREF
1
<2.0VP-P
0
≥2.0VP-P
REFERENCE OUTPUT BUFFER
The reference output buffer produces a low noise square
wave with a noise floor of –155dBc/Hz (typical) at 10MHz.
Its output is low impedance, and produces 0dBm typical
output power into a 50Ω load at 10MHz. Larger output
swings will result if driving larger impedances. The output is self-biased, and must be AC-coupled with a 22nF
capacitor (see Figure 2 for a simplified schematic). The
buffer may be powered down by using bit PDREFO found
in the serial port Power register h02.
BST
VREFO+
Figure 1. Simplified REF Interface Schematic
A high quality signal must be applied to the REF± inputs
as they provide the frequency reference to the entire PLL.
To achieve the part’s in-band phase noise performance,
apply a CW signal of at least 6dBm into 50Ω, or a square
wave of at least 0.5VP-P with slew rate of at least 40V/µs.
Additional options are available through serial port register
h08 to further refine the application. Bits FILT[1:0] control
the reference input buffer’s lowpass filter, and should be
set based upon fREF to limit the reference’s wideband
noise. The FILT[1:0] bits must be set correctly to reach
the LM(NORM) normalized in-band phase noise floor. See
Table 1 for recommended settings.
14
REFO
2
800Ω
6946 F02
Figure 2. Simplified REFO Interface Schematic
6946fb
For more information www.linear.com/LTC6946
LTC6946
Operation
REFERENCE (R) DIVIDER
A 10-bit divider, R_DIV, is used to reduce the frequency
seen at the PFD. Its divide ratio R may be set to any
integer from 1 to 1023, inclusive. Use the RD[9:0] bits
found in registers h03 and h04 to directly program the R
divide ratio. See the Applications Information section for
the relationship between R and the fREF , fPFD, fVCO and
fRF frequencies.
PHASE/FREQUENCY DETECTOR (PFD)
The phase/frequency detector (PFD), in conjunction with
the charge pump, produces source and sink current pulses
proportional to the phase difference between the outputs
of the R and N dividers. This action provides the necessary
feedback to phase-lock the loop, forcing a phase alignment at the PFD’s inputs. The PFD may be disabled with
the CPRST bit which prevents UP and DOWN pulses from
being produced. See Figure 3 for a simplified schematic
of the PFD.
D
Q
The user sets the phase difference lock window time,
tLWW, for a valid LOCK condition with the LKWIN[1:0]
bits. See Table 3 for recommended settings for different
FPFD frequencies and the Applications Information section for examples.
Table 3. LKWIN[1:0] Programming
LKWIN[1:0]
0
1
2
3
Table 4. LKCNT[1:0] Programming
LKCNT[1:0]
0
1
2
3
R DIV
CPRST
DELAY
D
Q
DOWN
6946 F03
N DIV
fPFD
>5MHz
≤5MHz
≤1.7MHz
≤550kHz
The PFD phase difference must be less than tLWW for the
LOKCNT number of successive counts before the lock
indicator asserts the LOCK flag. The LKCNT[1:0] bits found
in register h09 are used to set LOKCNT depending upon
the application. See Table 4 for LKCNT[1:0] programming
and the Applications Information section for examples.
UP
RST
tLWW
3ns
10ns
30ns
90ns
COUNTS
32
128
512
2048
When the PFD phase difference is greater than tLWW , the
lock indicator immediately asserts the UNLOCK status
flag and clears the LOCK flag, indicating an out-of-lock
condition. The UNLOCK flag is immediately de-asserted
when the phase difference is less than tLWW . See Figure 4
for more details.
RST
+tLWW
Figure 3. Simplified PFD Schematic
PHASE
DIFFERENCE
AT PFD
0
–tLWW
LOCK INDICATOR
The lock indicator uses internal signals from the PFD to
measure phase coincidence between the R and N divider
output signals. It is enabled by setting the LKEN bit in
the serial port register h07, and produces both LOCK and
UNLOCK status flags, available through both the STAT
output and serial port register h00.
UNLOCK FLAG
t = COUNTS/fPFD
LOCK FLAG
6946 F04
Figure 4. UNLOCK and LOCK Timing
6946fb
For more information www.linear.com/LTC6946
15
LTC6946
Operation
CHARGE PUMP
The charge pump, controlled by the PFD, forces sink
(DOWN) or source (UP) current pulses onto the CP pin,
which should be connected to an appropriate loop filter.
See Figure 5 for a simplified schematic of the charge pump.
VCP+
CHARGE PUMP FUNCTIONS
VCP+
+
–
UP
CPUP
CPMID
0.9V
–
+
THI
CP
VCP+/2
–
+
DOWN
CPDN
+
–
The CPINV bit found in register h0A should be set for
applications requiring signal inversion from the PFD,
such as for complex external loops using an inverting op
amp. A passive loop filter as shown in Figure 14 requires
CPINV = 0.
The charge pump contains additional features to aid
in system start-up and monitoring. See Table 6 for a
summary.
Table 6. Charge Pump Function Bit Descriptions
25
TLO
0.9V
6946 F05
BIT
DESCRIPTION
CPCHI
Enable High Voltage Output Clamp
CPCLO
Enable Low Voltage Output Clamp
CPDN
Force Sink Current
CPINV
Invert PFD Phase
CPMID
Enable Mid-Voltage Bias
Figure 5. Simplified Charge Pump Schematic
CPRST
Reset PFD
The output current magnitude ICP may be set from 250µA to
11.2mA using the CP[3:0] bits found in serial port register
h09. A larger ICP can result in lower in-band noise due to
the lower impedance of the loop filter components. See
Table 5 for programming specifics and the Applications
Information section for loop filter examples.
CPUP
Force Source Current
CPWIDE
Extend Current Pulse Width
THI
High Voltage Clamp Flag
TLO
Low Voltage Clamp Flag
Table 5. CP[3:0] Programming
CP[3:0]
0
1
2
3
4
5
6
7
8
9
10
11
12 to 15
16
ICP
250µA
350µA
500µA
700µA
1.0mA
1.4mA
2.0mA
2.8mA
4.0mA
5.6mA
8.0mA
11.2mA
Invalid
The CPCHI and CPCLO bits found in register h0A enable
the high and low voltage clamps, respectively. When
CPCHI is enabled and the CP pin voltage exceeds approximately VCP+ – 0.9V, the THI status flag is set, and
the charge pump sourcing current is disabled. Alternately,
when CPCLO is enabled and the CP pin voltage is less
than approximately 0.9V, the TLO status flag is set, and
the charge pump sinking current is disabled. See Figure
5 for a simplified schematic.
The CPMID bit also found in register h0A enables a resistive VCP+/2 output bias which may be used to pre-bias
troublesome loop filters into a valid voltage range. When
using CPMID, it is recommended to also assert the CPRST
bit, forcing a PFD reset. Both CPMID and CPRST must be
set to “0” for normal operation.
6946fb
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LTC6946
Operation
The CPUP and CPDN bits force a constant ICP source or
sink current, respectively, on the CP pin. The CPRST bit
may also be used in conjunction with the CPUP and CPDN
bits, allowing a pre-charge of the loop to a known state,
if required. CPUP, CPDN, and CPRST must be set to “0”
to allow the loop to lock.
The CPWIDE bit extends the charge pump output current
pulse width by increasing the PFD reset path’s delay value
(see Figure 3). CPWIDE is normally set to 0.
VCO
The integrated VCO is available in one of three frequency
ranges. The output frequency range may be further extended by utilizing the output divider (see Available Options
table, for more details). The wide frequency range of the
VCO, coupled with the output divider capability, allows the
LTC6946 to cover an extremely wide range of continuously
selectable frequencies.
VCO Calibration
The VCO must be calibrated each time its frequency is
changed by either fREF , the R divider, or N divider, but not
the O divider (see the Applications Information section for
the relationship between R, N, O, and the fREF , fPFD, fVCO
and fRF frequencies). The output frequency is then stable
over the LTC6946’s entire temperature range, regardless
of the temperature at which it was calibrated, until the
part is reset due to a power cycle or software power-on
reset (POR).
The output of the B divider is used to clock digital calibration circuitry as shown in the Block Diagram. The B value,
programmed with bits BD[3:0], is determined according
to Equation 1.
B≥
fPFD
fCAL-MAX The maximum calibration frequency fCAL-MAX for each part
option is shown in Table 7.
Table 7. Maximum Calibration Frequency
PART
fCAL-MAX (MHz)
LTC6946-1
1.0
LTC6946-2
1.33
LTC6946-3
1.7
LTC6946-4
1.8
The relationship between bits BD[3:0] and the B value is
shown in Table 8.
Table 8. BD[3:0] Programming
BD[3:0]
0
1
2
3
4
5
6
7
8
9
10
11
12 to 15
B DIVIDE VALUE
8
12
16
24
32
48
64
96
128
192
256
384
Invalid
The VCO may be calibrated once the RD[9:0], ND[15:0],
and BD[3:0] bits are written. The reference frequency fREF
must also be present and stable at the REF± inputs.
A calibration cycle is initiated each time the CAL bit is written to “1” (the bit is self-clearing). The calibration cycle
takes between 12 and 14 cycles of the B divider output.
(1)
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17
LTC6946
Operation
VCO Automatic Level Control (ALC)
The VCO uses an internal automatic level control (ALC)
algorithm to maintain an optimal amplitude on the VCO
resonator, and thus optimal phase noise performance. The
user has several ALC configuration and status reporting
options as seen in Table 9.
Table 9. ALC Bit Descriptions
BIT
DESCRIPTION
ALCCAL
Auto Enable ALC During CAL Operation
ALCEN
Always Enable ALC (Overrides ALCCAL, ALCMON and
ALCULOK)
ALCHI
ALC Too High Flag (Resonator Amplitude Too High)
ALCLO
ALC Too Low Flag (Resonator Amplitude Too Low)
ALCMON
Enable ALC Monitoring for Status Flags Only; Does NOT
Enable Amplitude Control
ALCULOK
Auto Enable ALC when PLL Unlocked
Changes in the internal ALC output can cause extremely
small jumps in the VCO frequency. These jumps may be
acceptable in some applications but not in others. Use the
above table to choose when the ALC is active. The ALCHI
and ALCLO flags, valid only when the ALC is active or the
ALCMON bit is set, may be used to monitor the resonator
amplitude.
The ALC must be allowed to operate during or after a
calibration cycle. At least one of the ALCCAL, ALCEN or
ALCULOK bits must be set.
OD[2:0] bits found in register h08 to directly program the
0 divide ratio. See the Applications Information section
for the relationship between O and the fREF , fPFD, fVCO and
fRF frequencies.
RF OUTPUT BUFFER
The low noise, differential output buffer produces a differential output power of –6dBm to 3dBm, settable with
bits RFO[1:0] according to Table 10. The outputs may be
combined externally, or used individually. Terminate any
unused output with a 50Ω resistor to VRF+.
Table 10. RFO[1:0] Programming
RFO[1:0}
PRF (Differential)
PRF (Single Ended)
0
–6dBm
–9dBm
1
–3dBm
–6dBm
2
0dBm
–3dBm
3
3dBm
0dBm
Each output is open collector with 136Ω pull-up resistors
to VRF+, easing impedance matching at high frequencies.
See Figure 6 for circuit details and the Applications Information section for matching guidelines. The buffer may
be muted with either the OMUTE bit, found in register
h02, or by forcing the MUTE input low.
VRF+
VRF+
136Ω
136Ω
VCO (N) DIVIDER
The 16-bit N divider provides the feedback from the VCO
to the PFD. Its divide ratio N may be set to any integer
from 32 to 65535, inclusive. Use the ND[15:0] bits found
in registers h05 and h06 to directly program the N divide
ratio. See the Applications Information section for the
relationship between N and the fREF , fPFD, fVCO and fRF
frequencies.
RF+
RF–
9
MUTE
OMUTE
12
11
MUTE
RFO[1:0]
6946 F06
Figure 6. Simplified RF Interface Schematic
OUTPUT (O) DIVIDER
The 3-bit O divider can reduce the frequency from the VCO
to extend the output frequency range. Its divide ratio O
may be set to any integer from 1 to 6, inclusive, outputting
a 50% duty cycle even with odd divide values. Use the
18
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LTC6946
Operation
SERIAL PORT
Single Byte Transfers
The SPI-compatible serial port provides control and monitoring functionality. A configurable status output, STAT,
gives additional instant monitoring.
The serial port is arranged as a simple memory map, with
status and control available in 12, byte-wide registers. All
data bursts are comprised of at least two bytes. The 7 most
significant bits of the first byte are the register address,
with an LSB of 1 indicating a read from the part, and LSB
of 0 indicating a write to the part. The subsequent byte,
or bytes, is data from/to the specified register address.
See Figure 9 for an example of a detailed write sequence,
and Figure 10 for a read sequence.
Communication Sequence
The serial bus is comprised of CS, SCLK, SDI and SDO.
Data transfers to the part are accomplished by the serial bus master device first taking CS low to enable the
LTC6946’s port. Input data applied on SDI is clocked on
the rising edge of SCLK, with all transfers MSB first. The
communication burst is terminated by the serial bus master
returning CS high. See Figure 7 for details.
Figure 11 shows an example of two write communication
bursts. The first byte of the first burst sent from the serial
bus master on SDI contains the destination register address
(Addr0) and an LSB of “0” indicating a write. The next byte
is the data intended for the register at address Addr0. CS is
then taken high to terminate the transfer. The first byte of
the second burst contains the destination register address
(Addr1) and an LSB indicating a write. The next byte on
SDI is the data intended for the register at address Addr1.
CS is then taken high to terminate the transfer.
Data is read from the part during a communication burst
using SDO. Readback may be multidrop (more than one
LTC6946 connected in parallel on the serial bus), as SDO
is three-stated (Hi-Z) when CS = 1, or when data is not
being read from the part. If the LTC6946 is not used in
a multidrop configuration, or if the serial port master is
not capable of setting the SDO line level between read
sequences, it is recommended to attach a high value
resistor of greater than 200k between SDO and GND to
ensure the line returns to a known level during Hi-Z states.
See Figure 8 for details.
MASTER–CS
tCSS
tCKL
tCKH
tCSS
tCSH
MASTER–SCLK
tCS
MASTER–SDI
tCH
DATA
DATA
6946 F07
Figure 7. Serial Port Write Timing Diagram
MASTER–CS
8TH CLOCK
MASTER–SCLK
tDO
LTC6946–SDO
Hi-Z
tDO
tDO
tDO
DATA
DATA
Hi-Z
6946 F08
Figure 8. Serial Port Read Timing Diagram
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19
LTC6946
Operation
Multiple Byte Transfers
on. If the resister address pointer attempts to increment
past 11 (h0B), it is automatically reset to 0.
More efficient data transfer of multiple bytes is accomplished by using the LTC6946’s register address autoincrement feature as shown in Figure 12. The serial port
master sends the destination register address in the first
byte and its data in the second byte as before, but continues
sending bytes destined for subsequent registers. Byte 1’s
address is Addr0+1, Byte 2’s address is Addr0+2, and so
An example of an auto-increment read from the part is
shown in Figure 13. The first byte of the burst sent from
the serial bus master on SDI contains the destination register address (Addr0) and an LSB of “1” indicating a read.
Once the LTC6946 detects a read burst, it takes SDO out
of the Hi-Z condition and sends data bytes sequentially,
MASTER–CS
16 CLOCKS
MASTER–SCLK
7-BIT REGISTER ADDRESS
8 BITS OF DATA
A6 A5 A4 A3 A2 A1 A0 0 D7 D6 D5 D4 D3 D2 D1 D0
MASTER–SDI
0 = WRITE
Hi-Z
LTC6946–SD0
6946 F09
Figure 9. Serial Port Write Sequence
MASTER–CS
16 CLOCKS
MASTER–SCLK
7-BIT REGISTER ADDRESS
1 = READ
A6 A5 A4 A3 A2 A1 A0 1
MASTER–SDI
8 BITS OF DATA
Hi-Z
LTC6946–SDO
X D7 D6 D5 D4 D3 D2 D1 D0 DX
Hi-Z
6946 F10
Figure 10. Serial Port Read Sequence
MASTER–CS
Addr0 + Wr
MASTER–SDI
LTC6946–SDO
Byte 0
Addr1 + Wr
Byte 1
Hi-Z
6946 F11
Figure 11. Serial Port Single Byte Write
MASTER–CS
Addr0 + Wr
MASTER–SDI
LTC6946–SDO
Byte 0
Byte 1
Hi-Z
6946 F12
Figure 12. Serial Port Auto-Increment Write
20
Byte 2
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6946fb
LTC6946
Operation
MASTER–CS
Addr0 + Rd
MASTER–SDI
DON’T CARE
Hi-Z
LTC6946–SDO
Byte 0
Byte 1
Hi-Z
Byte 2
6946 F13
Figure 13. Serial Port Auto-Increment Read
beginning with data from register Addr0. The part ignores
all other data on SDI until the end of the burst.
Serial Port Registers
The memory map of the LTC6946 may be found in Table 11,
with detailed bit descriptions found in Table 12. The register
address shown in hexadecimal format under the ADDR
column is used to specify each register. Each register is
denoted as either read-only (R) or read-write (R/W). The
register’s default value on device power-up or after a reset
is shown at the right.
Multidrop Configuration
Several LTC6946s may share the serial bus. In this multidrop configuration, SCLK, SDI, and SDO are common
between all parts. The serial bus master must use a separate
CS for each LTC6946 and ensure that only one device has
CS asserted at any time. It is recommended to attach a
high value resistor to SDO to ensure the line returns to a
known level during Hi-Z states.
The read-only register at address h00 is used to determine
different status flags. These flags may be instantly output
on the STAT pin by configuring register h01. See the STAT
Output section for more information.
The read-only register at address h0B is a ROM byte for
device identification.
Table 11. Serial Port Register Contents
ADDR
MSB
[6]
[5]
[4]
[3]
[2]
[1]
LSB
R/W
h00
*
*
UNLOCK
ALCHI
ALCLO
LOCK
THI
TLO
R
DEFAULT
h01
*
*
x[5]
x[4]
x[3]
x[2]
x[1]
x[0]
R/W
h04
h02
PDALL
PDPLL
PDVCO
PDOUT
PDREFO
MTCAL
OMUTE
POR
R/W
h0E
h03
BD[3]
BD[2]
BD[1]
BD[0]
*
*
RD[9]
RD[8]
R/W
h30
h04
RD[7]
RD[6]
RD[5]
RD[4]
RD[3]
RD[2]
RD[1]
RD[0]
R/W
h01
h05
ND[15]
ND[14]
ND[13]
ND[12]
ND[11]
ND[10]
ND[9]
ND[8]
R/W
h00
h06
ND[7]
ND[6]
ND[5]
ND[4]
ND[3]
ND[2]
ND[1]
ND[0]
R/W
hFA
h07
ALCEN
ALCMON
ALCCAL
ALCULOK
*
*
CAL
LKEN
R/W
h21
h08
BST
FILT[1]
FILT[0]
RFO[1]
RFO[0]
OD[2]
OD[1]
OD[0]
R/W
hF9
h09
LKWIN[1]
LKWIN[0]
LKCT[1]
LKCT[0]
CP[3]
CP[2]
CP[1]
CP[0]
R/W
h9B
h0A
CPCHI
CPCLO
CPMID
CPINV
CPWIDE
CPRST
CPUP
CPDN
R/W
hE4
h0B
REV[2]
REV[1]
REV[0]
PART[4]
PART[3]
PART[2]
PART[1]
PART[0]
R
hxx†
*unused †varies depending on version
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21
LTC6946
Operation
STAT Output
Table 12. Serial Port Register Bit Field Summary
BITS
DESCRIPTION
DEFAULT
ALCCAL
Auto Enable ALC During CAL Operation
1
ALCEN
Always Enable ALC (Override)
1
ALCHI
ALC Too Hi Flag
ALCLO
ALC Too Low Flag
The STAT output pin is configured with the x[5:0] bits
of register h01. These bits are used to bit-wise mask, or
enable, the corresponding status flags of status register
h00, according to Equation 2. The result of this bit-wise
Boolean operation is then output on the STAT pin:
ALCMON
Enable ALC Monitor for Status Flags Only
0
ALCULOK
Enable ALC When PLL Unlocked
0
STAT = OR (Reg00[5:0] AND Reg01[5:0])
BD[3:0]
Calibration B Divider Value
h3
BST
REF Buffer Boost Current
1
or expanded:
CAL
Start VCO Calibration (auto clears)
0
STAT = (UNLOCK AND x[5]) OR
CP[3:0]
CP Output Current
hB
CPCHI
CP Enable Hi Voltage Output Clamp
1
(ALCHI AND x[4]) OR
CPCLO
CP Enable Low Voltage Output Clamp
1
(ALCLO AND x[3]) OR
CPDN
CP Pump Down Only
0
CPINV
CP Invert Phase
0
(LOCK AND x[2]) OR
CPMID
CP Bias to Mid-Rail
1
(THI AND x[1]) OR
CPRST
CP Three-State
1
(TLO AND x[0])
CPUP
CP Pump Up Only
0
CPWIDE
CP Extend Pulse Width
0
FILT[1:0]
REF Input Buffer Filter
h3
LKCT[1:0]
PLL Lock Cycle Count
h1
For example, if the application requires STAT to go high
whenever the ALCHI, ALCLO, or THI flags are set, then
x[4], x[3], and x[1] should be set to “1”, giving a register
value of h1A.
LKEN
PLL Lock Indicator Enable
1
LKWIN[1:0] PLL Lock Indicator Window
LOCK
h2
PLL Lock Indicator Flag
MTCAL
Mutes Output During Calibration
1
ND[15:0]
N Divider Value (ND[15:0] > 31)
h00FA
OD[2:0]
Output Divider Value (0 < OD[2:0] < 7)
OMUTE
Mutes RF Output
PART[4:0]
h1
1
Part code (h01 for LTC6946-1, h02 for
LTC6946-2, h03 for LTC6946-3, h04 for
LTC6946-4 Version)
h01, h02,
h03, h04
PDALL
Full Chip Power Down
0
PDOUT
Powers Down O_DIV, RF Output Buffer
0
PDPLL
Powers Down REF, REFO, R_DIV, PFD,
CPUMP, N_DIV
0
PDREFO
Powers Down REFO
1
PDVCO
Powers Down VCO, N_DIV
0
POR
Force Power-On Reset
RD[9:0]
R Divider Value (RD[9:0] > 0)
REV[2:0]
Rev Code
RFO[1:0]
RF Output Power
THI
CP Clamp High Flag
TLO
CP Clamp Low Flag
UNLOCK
x[5:0]
22
(2)
Block Power-Down Control
The LTC6946’s power-down control bits are located in
register h02, described in Table 12. Different portions of
the device may be powered down independently. Care must
be taken with the LSB of the register, the POR (power-on
reset) bit. When written to a “1”, this bit forces a full reset
of the part’s digital circuitry to its power-up default state.
0
h001
h3
PLL Unlock Flag
STAT Output OR Mask
h04
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LTC6946
Applications Information
INTRODUCTION
A PLL is a complex feedback system that may conceptually
be considered a frequency multiplier. The system multiplies
the frequency input at REF± and outputs a higher frequency
at RF±. The PFD, charge pump, N divider, and external VCO
and loop filter form a feedback loop to accurately control
the output frequency (see Figure 14). The R and O divider
are used to set the output frequency resolution.
LTC6946
REF±
(fREF)
R_DIV
ICP
fPFD
÷R
CP
LOOP FILTER
25
RZ
KPFD
CP
CI
N_DIV
LF(s)
÷N
RF±
O_DIV
(fRF)
÷O
TUNE
fVCO
15
6946 F14
KVCO
Figure 14. PLL Loop Diagram
OUTPUT FREQUENCY
When the loop is locked, the frequency fVCO (in Hz)
produced at the output of the VCO is determined by the
reference frequency, fREF , and the R and N divider values,
given by Equation 3:
fVCO =
fREF • N
R (3)
Here, the PFD frequency fPFD produced is given by the
following equation:
fPFD =
fREF
R (4)
and fVCO may be alternatively expressed as:
fVCO = fPFD • N
The output frequency fRF produced at the output of the O
divider is given by Equation 5:
fRF =
fVCO
O Using the above equations, the output frequency resolution
fSTEP produced by a unit change in N is given by Equation 6:
fSTEP =
fREF
R•O (6)
LOOP FILTER DESIGN
A stable PLL system requires care in selecting the external
loop filter values. The Linear Technology PLLWizard application, available from www.linear.com, aids in design
and simulation of the complete system.
The loop design should use the following algorithm:
1.Determine the output frequency, fRF , and frequency step
size, fSTEP , based on application requirements. Using
Equations 3, 4, 5 and 6, change fREF , N, R, and O until
the application frequency constraints are met. Use the
minimum R value that still satisfies the constraints.
Then calculate B using Equation 1 and Table 7.
2.Select the open-loop bandwidth, BW, constrained by
fPFD. A stable loop requires that BW is less than fPFD
by at least a factor of 10.
3.Select loop filter component RZ and charge pump current ICP based on BW and the VCO gain factor, KVCO.
BW (in Hz) is approximated by the following equation:
BW ≅
ICP • RZ • K VCO
2 • π •N
(7)
or
RZ =
2 • π • BW • N
ICP • K VCO
where KVCO is in Hz/V, ICP is in Amps, and RZ is in
Ohms.
KVCO is obtained from the VCO tuning sensitivity in the
Electrical Characteristics. Use ICP = 11.2mA to lower inband noise unless component values force a lower setting.
(5)
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23
LTC6946
Applications Information
4.Select loop filter components CI and CP based on BW
and RZ. A reliable loop can be achieved by using the
following equations for the loop capacitors (in Farads):
3.5
CI = 2 • π • BW • R Z
1
CP =
7 • π • BW • RZ (8)
(9)
DESIGN AND PROGRAMMING EXAMPLE
power. Use a factor of 15 for this design example:
250kHz
= 16.7kHz
15
Loop Filter Component Selection
Now set loop filter resistor, RZ, and charge pump current,
ICP . Because the KVCO varies over the VCO’s frequency
range, using the KVCO geometric mean gives good results.
Using an ICP of 11.2mA, RZ is determined:
K VCO = 4.8 • 109 • 0.04 • 0.06 = 235MHz / V
This programming example uses the DC1705A with the
LTC6946-3. Assume the following parameters of interest:
RZ =
fREF = 20MHz at 7dBm into 50Ω
fSTEP = 125kHz
BW =
2 • π • 16.7k • 19200
11.2m • 235M
RZ = 765Ω
fRF = 2.4GHz
Now calculate CI and CP from Equations 7 and 8:
From the Electrical Characteristics table:
CI =
fVCO = 3.840GHz to 5.790GHz
KVCO% = 4.0%Hz/V to 6.0%Hz/V
Determining Divider Values
Following the Loop Filter Design algorithm, first determine all the divider values. Using Equations 2, 3, 4 and 5
calculate the following values:
O=2
R = 20MHz/(125kHz • 2) = 80
fPFD = 250kHz
3.5
= 44nF
2 • π • 16.7k • 765
CP =
1
= 3.6nF
7 • π • 16.7k • 765
Status Output Programming
This example will use the STAT pin to alert the system
whenever the LTC6946 generates a fault condition. Program x[5], x[4], x[3], x[1], x[0] = 1 to force the STAT pin
high whenever any of the UNLOCK, ALCHI, ALCLO, THI
or TLO flags asserts:
N = 2 • 2.4GHz/250kHz = 19200
Reg01 = h3B
fVCO = 4.8GHz
Power Register Programming
Also, from Equation 1 or Table 7 determine B:
For correct PLL operation all internal blocks should be
enabled, but PDREFO should be set if the REFO pin is
not being used. OMUTE may remain asserted (or the
MUTE pin held low) until programming is complete. For
PDREFO = 1 and OMUTE = 1:
B = 8 and BD[3:0] = 0
The next step in the algorithm is to determine the openloop bandwidth. BW should be at least 10× smaller than
fPFD. Wider loop bandwidths could have lower integrated
phase noise, depending on the VCO phase noise signature,
while narrower bandwidths will likely have lower spurious
24
Reg02 = h0A
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LTC6946
Applications Information
Divider Programming
Program registers Reg03 to Reg06 with the previously
determined B, R and N divider values.
Reg03 = h00
Reg04 = h50
Reg05 = h4B
Reg06 = h00
VCO ALC and Calibration Programming
Now that all the divider registers are programmed, and
assuming that the reference frequency is stable at REF±,
calibrate the VCO. Set the ALC options (ALCMON = 1,
ALCCAL = 1) and the lock enable bit (LKEN = 1) at the
same time:
Reg07 = h63
The LTC6946 will now calibrate its VCO. The ALC will only
be active during the calibration cycle, but the ALCHI and
ALCLO status conditions will be monitored.
Reference Input Settings and Output Divider
Programming
From Table 1, FILT = 1 for a 20MHz reference frequency.
Next, convert 7dBm into VP-P . For a CW tone, use the
following equation with R = 50:
(dBm – 21)/20
VP-P ≅ R • 10
(10)
This gives VP-P = 1.41V, and, according to Table 2, set
BST = 1.
Now program Reg08, assuming maximum RF± output
power (RFO[1:0] = 3 according to Table 9) and OD[2:0] = 2:
Reg08 = hBA
Lock Detect and Charge Pump Current Programming
Next, determine the lock indicator window from fPFD.
From Table 3, LKWIN[1:0] = 3 for a tLWW of 90ns. The
LTC6946 will consider the loop “locked” as long as the
phase coincidence at the PFD is within 8°, as calculated:
phase = 360° • tLWW • fPFD = 360 • 90n • 250k ≅ 8°
LKWIN[1:0] may be set to a smaller value to be more
conservative. However, the inherent phase noise of the
loop could cause false “unlocks” for too small a value.
Choosing the correct LOKCNT depends upon the ratio of
the bandwidth of the loop to the PFD frequency (BW/fPFD).
Smaller ratios dictate larger LOKCNT values. A LOKCNT
value of 128 will work for our ratio of 1/15. From Table 4,
LKCNT[1:0] = 1 for 128 counts.
Using Table 5 with the previously selected ICP of 11.2mA,
gives CP[3:0] = 11 (hB). This is enough information to
program Reg09:
Reg09 = hDB
Charge Pump Function Programming
This example uses the additional voltage clamp features to
allow us to monitor fault conditions by setting CPCHI = 1
and CPCLO = 1. If something occurs and the system can
no longer lock to its intended frequency, the charge pump
output will move toward either GND or VCP+, thereby setting
either the TLO or THI status flags, respectively. Disable all
the other charge pump functions (CPMID, CPINV, CPRST,
CPUP and CPDN) to allow the loop to lock:
Reg0A = hC0
The loop should now lock. Now unmute the output by
setting OMUTE = 0 (assumes the MUTE pin is high):
Reg02 = h08
REFERENCE SOURCE CONSIDERATIONS
A high quality signal must be applied to the REF± inputs as
they provide the frequency reference to the entire PLL. As
mentioned previously, to achieve the part’s in-band phase
noise performance, apply a CW signal of at least 6dBm
into 50Ω, or a square wave of at least 0.5VP-P with slew
rate of at least 40V/µs.
The LTC6946 may be driven single ended to CMOS levels
(greater than 2.7VP-P ). Apply the reference signal directly
without a DC-blocking capacitor at REF+, and bypass REF–
to GND with a 47pF capacitor. The BST bit must also be
set to “0”, according to guidelines given in Table 2.
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For more information www.linear.com/LTC6946
25
LTC6946
Applications Information
The LTC6946 achieves an in-band normalized phase noise
floor of –226dBc/Hz (typical). To calculate its equivalent input phase noise floor LM(IN), use the following
Equation 11:
over offset frequency. See Figure 15 for an example of
in-band phase noise for fPFD equal to 3MHz and 100MHz.
The total phase noise will be the summation of LM(OUT)
and LM(OUT 1/f).
LM(IN) = –226 + 10 • log10(fREF)(11)
IN-BAND OUTPUT PHASE NOISE
The in-band phase noise produced at fRF may be calculated by using Equation 12.
(12)
LM(OUT) = –226 + 10 • log10 ( fPFD )
As can be seen, for a given PFD frequency fPFD, the output
in-band phase noise increases at a 20dB-per-decade rate
with the N divider count. So, for a given output frequency
fRF, fPFD should be as large as possible (or N should be as
small as possible) while still satisfying the application’s
frequency step size requirements.
OUTPUT PHASE NOISE DUE TO 1/f NOISE
In-band phase noise at very low offset frequencies may
be influenced by the LTC6946’s 1/f noise, depending upon
fPFD. Use the normalized in-band 1/f noise of –274dBc/
Hz with Equation 13 to approximate the output 1/f phase
noise at a given frequency offset fOFFSET.
(13)
LM(OUT-1/ f) ( fOFFSET ) = –274+ 20 • log10 ( fRF )
–10 • log10 ( fOFFSET )
Unlike the in-band noise floor LM(OUT), the 1/f noise
LM(OUT 1/f) does not change with fPFD, and is not constant
26
TOTAL NOISE
fPFD = 100MHz
–110
–120
1/f NOISE
CONTRIBUTION
–130
10
1k
10k
100
OFFSET FREQUENCY (Hz)
100k
6945 F15
RF OUTPUT MATCHING
LM(OUT) = –226 + 10 • log10 ( fPFD )
 N
+ 20 • log10  
 O
TOTAL NOISE
fPFD = 3MHz
–100
Figure 15. Theoretical In-Band Phase Noise, fRF = 2500MHz
 f 
+ 20 • log10  RF 
 fPFD 
or
PHASE NOISE (dBc/Hz)
For example, using a 10MHz reference frequency gives
an input phase noise floor of –156dBc/Hz. The reference
frequency source’s phase noise must be at least 3dB better
than this to prevent limiting the overall system performance.
–90
The RF± outputs may be used in either single-ended or differential configurations. Using both RF outputs differentially
will result in approximately 3dB more output power than
single ended. Impedance matching to an external load in
both cases requires external chokes tied to VRF+. Measured
RF± s-parameters are shown below in Table 13 to aid in
the design of impedance matching networks.
Table 13. Single-Ended RF Output Impedance
FREQUENCY (MHZ)
500
1000
1500
2000
2500
3000
3500
4000
4500
5000
5500
6000
6500
7000
7500
8000
IMPEDANCE (Ohms)
102.8 – j49.7
70.2 – j60.1
52.4 – j56.2
43.6 – j49.2
37.9 – j39.6
32.7 – j28.2
27.9 – j17.8
24.3 – j9.4
22.2 – j3.3
21.6 + j1.9
21.8 + j6.6
23.1 + j11.4
25.7 + j16.9
29.3 + j23.0
33.5 + j28.4
37.9 + j32.6
S11 (dB)
–6.90
–6.53
–6.35
–6.58
–7.34
–8.44
–8.99
–8.72
–8.26
–8.02
–7.91
–8.09
–8.38
–8.53
–8.56
–8.64
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For more information www.linear.com/LTC6946
LTC6946
Applications Information
Table 14. Suggested Single-Ended Matching Component Values
fRF (MHz)
LC (nH)
CS (pF)
350 to 1500
180
270
1000 to 5800
68
100
Return loss measured on the DC1705 using the above
component values is shown in Figure 17. A broadband
match is achieved using an (LC, CS) of either (68nH, 100pF)
or (180nH, 270pF). However, for maximum output power
and best phase noise performance, use the recommended
component values of Table 13. LC should be a wirewound
inductor selected for maximum Q factor and SRF, such
as the Coilcraft HP series of chip inductors.
The LTC6946’s differential RF± outputs may be combined
using an external balun to drive a single-ended load. The
advantages are approximately 3dB more output power than
each output individually and better 2nd order harmonic
performance.
For lower frequencies, transmission line (TL) baluns such
as the M/A-COM MABACT0065 and the TOKO #617DB1673 provide good results. At higher frequencies, surface
mount (SMT) baluns such as those produced by TDK,
Anaren, and Johanson Technology, can be attractive
alternatives. See Table 15 for recommended balun part
numbers versus frequency range.
VRF
+
LC
RF+(–)
0
68nH, 100pF
180nH, 270pF
–2
–4
–6
S11 (dB)
Single-ended impedance matching is accomplished
using the circuit of Figure 16, with component values
found in Table 14. Using smaller inductances than
recommended can cause phase noise degradation,
especially at lower center frequencies.
–8
–10
–12
–14
–16
0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 6
FREQUENCY (GHz)
6946 F17
Figure 17. Single-Ended Return Loss
The listed SMT baluns contain internal chokes to bias RF±
and also provide input-to-output DC isolation. The pin
denoted as GND or DC FEED should be connected to the
VRF+ voltage. Figure 18 shows a surface mount balun’s
connections with a DC FEED pin.
Table 15. Suggested Baluns
fRF (MHz)
350 to 900
PART NUMBER MANUFACTURER
#617DB-1673
TYPE
TOKO
TL
400 to 600
HHM1589B1
TDK
SMT
600 to 1400
BD0810J50200
Anaren
SMT
600 to 3000
MABACT0065
M/A-COM
TL
1000 to 2000
HHM1518A3
TDK
SMT
1400 to 2000
HHM1541E1
TDK
SMT
1900 to 2300
2450BL15B100E
Johanson
SMT
2000 to 2700
HHM1526
TDK
SMT
3700 to 5100
HHM1583B1
TDK
SMT
4000 to 6000
HHM1570B1
TDK
SMT
The listed TL baluns do not provide input-to-output DC
isolation and must be AC coupled at the output. Figure 18
displays RF± connections using these baluns.
CS
50Ω
VRF+
LC
RF–(+)
CS
TO 50Ω
LOAD
6946 F16
Figure 16. Single-Ended Output Matching Schematic
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For more information www.linear.com/LTC6946
27
LTC6946
Applications Information
VRF+
3
RF+ 12
LTC6946
RF–
2
1
TO 50Ω
LOAD
BALUN
11
4
5
6
6946 F18
6946 F20
BALUN PIN CONFIGURATION
1
UNBALANCED PORT
2
GND OR DC FEED
3
BALANCED PORT
4
BALANCED PORT
5
GND
6
NC
Figure 20. Example Exposed Pad Land Pattern
Figure 18. Example SMT Balun Connection
VRF+
TO 50Ω
LOAD
RF+ 12
LTC6946
RF–
PRI
11
SEC
6946 F19
Figure 19. Example TL Balun Connection
SUPPLY BYPASSING AND PCB LAYOUT GUIDELINES
Care must be taken when creating a PCB layout to minimize power supply decoupling and ground inductances.
All power supply V+ pins should be bypassed directly to
the ground plane using a 0.1µF ceramic capacitor as close
to the pin as possible. Multiple vias to the ground plane
should be used for all ground connections, including to
the power supply decoupling capacitors.
The package’s exposed pad is a ground connection, and
must be soldered directly to the PCB land. The PCB land
pattern should have multiple thermal vias to the ground
plane for both low ground inductance and also low thermal
resistance (see Figure 20 for an example). See QFN Package Users Guide, page 8, on Linear Technology website’s
Packaging Information page for specific recommendations
concerning land patterns and land via solder masks. A link
is provided below.
REFERENCE SIGNAL ROUTING, SPURIOUS and
phase noise
The charge pump operates at the PFD’s comparison
frequency fPFD. The resultant output spurious energy is
small and is further reduced by the loop filter before it
modulates the VCO frequency.
However, improper PCB layout can degrade the LTC6946’s
inherent spurious performance. Care must be taken to
prevent the reference signal fREF from coupling onto the
VCO’s tune line, or into other loop filter signals. Example
suggestions are the following.
1.Do not share power supply decoupling capacitors
between same voltage power supply pins.
2.Use separate ground vias for each power supply decoupling capacitor, especially those connected to VREF+,
VCP+, and VVCO+.
3.Physically separate the reference frequency signal from
the loop filter and VCO.
4.Do not place a trace between the CMA, CMB and CMC
pads underneath the package as worse phase noise
could result.
http://www.linear.com/designtools/packaging
28
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For more information www.linear.com/LTC6946
LTC6946
Applications Information
LTC6946-2 Driving a Modulator
0.01µF
3.3V
+
GND
CP
VCP+
VREF+
REF +
VREFO+
VVCO+
GND
STAT
CMA
CS
CMB
LTC6946-2
2.2µF
–60
≈–80dBc
–70
–80
–90
–90
MEASUREMENT NOISE FLOOR
–120
1802.5
GND
SDO
–40
–50
–110
CMC
SDI
0.1µF
0.01µF
REFO
SCLK
SPI BUS
15Ω
5V
3.3V
REF –
0.1µF
0.01µF
1µF
51.1Ω
MEASURED SIGNAL
–30
1µF
1µF
POWER IN 30kHz BW (dBm)
10MHz
REFERENCE
Measured W-CDMA ACPR
(3.84MHz Bandwidth)
BB
VRF+
RF+
RF–
GND
MUTE
VD+
3.3V
LOOP COMPENSATION
COMPONENT VALUES ARE
APPLICATION SPECIFIC
DEPENDING ON THE LO
FREQUENCY RANGE AND
STEP SIZE AND THE PHASE
NOISE OF THE REFERENCE
TUNE
RZ
CP
CI
1µF
3.3V
0.01µF
THE UNUSED RF – OUTPUT
IS AVAILABLE TO DRIVE
ANOTHER 50Ω LOAD
68nH
3.3V
68nH
1817.5
1812.5
1807.5
RF FREQUENCY (MHz)
TB
6946 TA02b
LTC6946-2 Modulator Application
Phase Noise
3.3V
–90
1nF
3.3V
1Ω
4.7µF
LO = 1950MHz
1.3Ω
1nF
LTC5588-1
VCC1
RF
EN
0°
90°
Q-DAC
BASEBAND
GENERATOR
10nF
–130
–140
RMS NOISE = 0.281°
fRF = 1950MHz
fPFD = 2MHz
OD = 2
fSTEP = 1MHz
1k
10k
100k
1M
OFFSET FREQUENCY (Hz)
10M
6946 TA02c
PA
1810MHz
GNDRF
BBPQ
–120
–160
100
1nF
VCC2
–110
–150
LOM
BBMI
EN
3.3V
4.7µF
LOP
BBPI
I-DAC
PHASE NOISE (dBc/Hz)
1nF
50Ω
–100
TOKO
4DFB-1950L-10
50Ω
VGA
BBMQ
140MHz
GND
LINOPT
6946 TA02
LTC2630
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For more information www.linear.com/LTC6946
29
LTC6946
Package Description
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
UFD Package
28-Lead Plastic QFN (4mm × 5mm)
(Reference LTC DWG # 05-08-1712 Rev B)
0.70 ±0.05
4.50 ± 0.05
3.10 ± 0.05
2.50 REF
2.65 ± 0.05
3.65 ± 0.05
PACKAGE OUTLINE
0.25 ±0.05
0.50 BSC
3.50 REF
4.10 ± 0.05
5.50 ± 0.05
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
4.00 ± 0.10
(2 SIDES)
0.75 ± 0.05
R = 0.05
TYP
PIN 1 NOTCH
R = 0.20 OR 0.35
× 45° CHAMFER
2.50 REF
R = 0.115
TYP
27
28
0.40 ± 0.10
PIN 1
TOP MARK
(NOTE 6)
1
2
5.00 ± 0.10
(2 SIDES)
3.50 REF
3.65 ± 0.10
2.65 ± 0.10
(UFD28) QFN 0506 REV B
0.200 REF
0.00 – 0.05
0.25 ± 0.05
0.50 BSC
BOTTOM VIEW—EXPOSED PAD
NOTE:
1. DRAWING PROPOSED TO BE MADE A JEDEC PACKAGE OUTLINE MO-220 VARIATION (WXXX-X).
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION
ON THE TOP AND BOTTOM OF PACKAGE
30
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For more information www.linear.com/LTC6946
LTC6946
Revision History
REV
DATE
DESCRIPTION
A
11/11
Add IOL and remove Max value, remove Max value for IOH
Revise values on Block Diagram
PAGE NUMBER
B
03/15
Added LTC6946-4.
4
11
All pages
Changed operating core temperature to operating junction temperature.
2
Updated power supply currents.
5
Updated VCO calibration.
8, 17
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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 representaFor more
information
www.linear.com/LTC6946
tion that the interconnection
of its circuits
as described
herein will not infringe on existing patent rights.
31
LTC6946
Typical Application
LTC6946-2 Driving a Passive Downconverting Mixer
0.01µF
3.3V
18
1µF
1µF
+
5V
GND
CP
VCP+
VVCO+
GND
STAT
CMA
15
14
13
12
11
9
–20
BB
VRF+
RF+
RF–
MUTE
TB
LOOP COMPENSATION
COMPONENT VALUES ARE
APPLICATION SPECIFIC
DEPENDING ON THE LO
FREQUENCY RANGE AND
STEP SIZE AND THE PHASE
NOISE OF THE REFERENCE
TUNE
RZ
CP
CI
1µF
3.3V
LO = LTC6946-2
LO = CLEAN LAB SOURCE
16
GND
SDO
RF = 1982MHz
BLOCKER = 2082MHz
10
CMC
SDI
V D+
2.2µF
CMB
LTC6946-2
SCLK
0.1µF
0.01µF
REFO
CS
SPI BUS
VREF+
REF –
VREFO+
REF +
3.3V
GND
0.1µF
15Ω
0.01µF
1µF
51.1Ω
17
SSB NOISE FIGURE (dB)
10MHz
REFERENCE
LTC5541 Noise Figure vs Blocker
Power and LO Signal Source
3.3V
0.01µF
0
–15
–5
–10
RF BLOCKER POWER (dBm)
5
6946 TA03b
LTC6946-2 Mixer Application
Phase Noise
–90
TOKO
3.3V
4DFB-1842N-10
3.3V
3.3V
22pF
RF IN
IMAGE
1952MHz
BPF
TO 2012MHZ
LO1
VCC1
LNA
1µF
22pF
VCC3
22pF
RF
150nH
IF+
150nH 1nF 140MHz
SAW
3.3V
CT
VCC2
–140
RMS NOISE = 0.270°
fRF = 1842MHz
fPFD = 2MHz
OD = 2
fSTEP = 1MHz
140MHz
BPF
1k
10k
100k
1M
OFFSET FREQUENCY (Hz)
10M
ADC
IFGND
6946 TA03
1nF
LTC5541
GND GND GND GND GND
–130
6946 TA03c
IF–
1.5pF
–120
–160
100
LOBIAS
IFBIAS
–110
–150
LOSEL
3.3V
2.2pF
PHASE NOISE (dBc/Hz)
LO = 1842MHz
BALUN TDK HHM1525
LO2
–100
SHDN
30nH
1µF
Related Parts
PART NUMBER
LTC6945
LTC6947
LTC6948
LTC6950
LTC6957
LTC2000
DESCRIPTION
Ultralow Noise and Spurious Integer-N Synthesizer
Ultralow Noise and Spurious Fractional-N Synthesizer
Ultralow Noise and Spurious Frac-N Synthesizer with VCO
Low Phase Noise and Spurious Integer-N PLL Core with Five
Output Clock Distribution and EZSync
Low Phase Noise, Dual Output Buffer/Driver/Logic Converter
16-/14-/11-Bit 2.5Gsps DAC
LTC5569
LTC5588-1
LT®5575
Broadband Dual Mixer
Ultrahigh OIP3 I/Q Modulator
Direct Conversion I/Q Demodulator
32 Linear Technology Corporation
COMMENTS
350MHz to 6GHz, –226dBc/Hz Normalized In-Band Phase Noise Floor
350MHz to 6GHz, –226dBc/Hz Normalized In-Band Phase Noise Floor
370MHz to 6.39GHz, –226dBc/Hz Normalized In-Band Phase Noise Floor
1.4GHz Max VCO Frequency, Additive Jitter <20fsRMS, –226dBc/Hz
Normalized In-Band Phase Noise Floor
Optimized Conversion of Sine Waves to Logic Levels, LVPECL/LVDS/CMOS
Superior 80dBc SFDR at 70MHz Output, 40mA Nominal Drive and High
Linearity
300MHz to 4GHz, 26.8dBm IIP3, 2dB Gain, 11.7dB NF, 600mW Power
200MHz to 6GHz, 31dBm OIP3, –160.6dBm/Hz Noise Floor
800MHz to 2.7GHz, 22.6dBm IIP3, 60dBm IIP2, 12.7dB NF
1630 McCarthy Blvd., Milpitas, CA 95035-7417
For more information www.linear.com/LTC6946
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com/LTC6946
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LT 0315 REV B • PRINTED IN USA
 LINEAR TECHNOLOGY CORPORATION 2011