LINER LTC6602IUF-PBF

LTC6602
Dual Matched, High
Frequency Bandpass/Lowpass Filters
DESCRIPTION
FEATURES
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Matched Dual Filter/Driver, Ideal for RFID Readers
Guaranteed Phase Matching to Within 2 Degrees
Guaranteed Gain Matching to Within 0.2dB
Configurable as Lowpass or Bandpass
Programmable 5th Order Lowpass: 42kHz to 900kHz
Programmable 4th Order Highpass: 4.2kHz to 90kHz
Programmable Gain: 1×, 4×, 16×, 32×
Simple Pin Programming or SPI Interface
Low Noise: –145dBm/Hz (Input Referred)
Low Distortion: –75dBc at 200kHz
Differential, Rail-to-Rail Inputs and Outputs
Input Range Extends from 0V to 5V
Low Voltage Operation: 2.7V to 3.6V
Shutdown Mode
4mm × 4mm QFN Package
APPLICATIONS
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Multiprotocol RFID Readers:
EPC-GEN2, ISD and IPX
IDEN, PHS, GSM Basestations
Repeaters, Radio Links, and Modems
Wireless Telemetry
JTRS
The LTC®6602 is a dual, matched, programmable bandpass
or lowpass filter and differential driver. The selectivity of the
LTC6602, combined with its phase matching and dynamic
range, make it ideal for filtering in RFID systems. With two
degree phase matching between channels, the LTC6602 can
be used in applications requiring highly matched filters,
such as transceiver I and Q channels. Gain programmability, and the fully differential inputs and outputs, simplify
implementation in most systems.
Both channels of the LTC6602 consist of a programmable
lowpass and highpass filter. For bandpass functionality,
the lowpass filters are programmed for the upper cutoff
frequency. For lowpass functionality, the highpass filters
can be bypassed. The filter cutoff frequencies can be set
with a guaranteed accuracy of 3% with the use of a single
resistor. Alternatively, the filter cutoff frequencies can be
controlled with an external clock.
The LTC6602 operates on a single 2.7V to 3.6V supply
and features a low power shutdown mode.
L, LT, LTC and LTM are registered trademarks of Linear Technology Corporation.
All other trademarks are the property of their respective owners..
TYPICAL APPLICATION
UHF RFID Reader Dual Baseband Filter and Dual ADC
Gain vs Frequency
3V
20
0.1μF
100Ω
I INPUT
Q INPUT
38.3k
0.1μF
MUTE
INPUT
FROM
TRANSMITTER
V+A
V+D
+INA
–OUTA
–INA
+OUTA
+INB
–OUTB
–INB
+OUTB
RBIAS
LTC6602
100pF
SER
MUTE
CLKCNTL
AIN–
I OUTPUT
VCM
2.2μF
Q OUTPUT
LTC2297
BIN+
100Ω
CLKIO
VOCM
14-BIT
ADC
100pF
100Ω
100pF
100pF
BIN–
14-BIT
ADC
GAIN0(D0) HPF0(SDO)
GAIN1
LPF0(SCLK)
GND
LPF1(CS)
–20
–30
–40
–60
1k
10k
100k
1M
FREQUENCY (Hz)
10M
6602 TA01b
HPF1(SDI)
GND
–10
–50 45kHz-300kHz BPF
100pF
100Ω
15kHz-150kHz BPF
90kHz-900kHz BPF
0
100pF
V+IN
EXTERNAL CLOCK = 90MHz
10
AIN+
GAIN (dB)
0.1μF
CLK IN
6602 TA01
CS SCLK SDI
SPI CONTROL INPUT
÷4
CLOCK INPUT
24MHz TO 128MHz
(COVERS THE TAG BACKSCATTER LINK FREQUENCY RANGE OF 40kHz to 640kHz
OF THE CLASS 1 GENERATION 2 UHF RFID COMMUNICATION PROTOCOL)
6602fa
1
LTC6602
ABSOLUTE MAXIMUM RATINGS
PIN CONFIGURATION
(Note 1)
+OUTA
MUTE
GAIN0(D0)
GAIN1
+INA
–INA
TOP VIEW
V+IN to GND ................................................................6V
V+A, V+D to GND .........................................................4V
Filter Inputs to GND ....................... –0.3V to V+IN + 0.3V
All Other Pins to GND.............. –0.3V to V+A, V+D + 0.3V
Maximum Input Current .......................................±10mA
Output Short Circuit Duration........................... Indefinite
Operating Temperature Range (Note 2)
LTC6602CUF ........................................ –40°C to 85°C
LTC6602IUF ......................................... –40°C to 85°C
Specified Temperature Range (Note 3)
LTC6602CUF ............................................ 0°C to 70°C
LTC6602IUF ......................................... –40°C to 85°C
Storage Temperature Range................... –65°C to 150°C
24 23 22 21 20 19
V+IN 1
18 –OUTA
V+A 2
17 SER
VOCM 3
16 V+D
25
RBIAS 4
15 CLKIO
–OUTB
9 10 11 12
HPFO(SDO)
8
HPF1(SDI)
7
LPFO(SCLK)
13 +OUTB
–INB
14 GND
LPF1(CS) 6
+INB
CLKCNTL 5
UF PACKAGE
24-LEAD (4mm × 4mm) PLASTIC QFN
TJMAX = 150°C, θJA = 37°C/W
EXPOSED PAD (PIN 25) IS GND, MUST BE SOLDERED TO THE PCB.
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
SPECIFIED TEMPERATURE RANGE
LTC6602CUF#PBF
LTC6602CUF#TRPBF
6602
24-Lead (4mm × 4mm) Plastic QFN
0°C to 70°C
LTC6602IUF#PBF
LTC6602IUF#TRPBF
6602
24-Lead (4mm × 4mm) Plastic QFN
–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.
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/
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which app ly over the full operating
temperature range, otherwise specifications are at TA = 25°C. V+A = V+D = V+IN = 3V, VICM = VOCM = 1.5V, Gain = 0dB, lowpass cutoff =
300kHz, highpass cutoff = 45kHz, internal clocking with RBIAS = 54.9k unless otherwise noted.
PARAMETER
CONDITIONS
Filter Gain Either Channel External Clock = 90MHz, Highpass Filter Cutoff = 45kHz,
Gain = 0dB
Lowpass Filter Cutoff = 300kHz, VIN = 3.6VP-P
fIN = 22.5kHz
fIN = 45kHz
fIN = 150kHz
fIN = 300kHz
fIN = 900kHz
Matching of Filter Gain
External Clock = 90MHz, Highpass Filter Cutoff = 45kHz,
Lowpass Filter Cutoff = 300kHz, VIN = 3.6VP-P
fIN = 45kHz
fIN = 150kHz
fIN = 300kHz
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MIN
TYP
MAX
UNITS
–1.8
0.1
–2.7
–32
–1.2
0.5
–2
–44
–30
–0.8
0.8
–1.2
–43
dB
dB
dB
dB
dB
±0.2
±0.2
±0.2
dB
dB
dB
6602fa
2
LTC6602
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. V+A = V+D = V+IN = 3V, VICM = VOCM = 1.5V, Gain = 0dB, lowpass cutoff =
300kHz, highpass cutoff = 45kHz, internal clocking with RBIAS = 54.9k unless otherwise noted.
PARAMETER
CONDITIONS
Filter Phase
Either Channel
External Clock = 90MHz, VIN = 3.6VP-P, Highpass Filter Cutoff = 45kHz,
Lowpass Filter Cutoff = 300kHz
fIN = 50kHz
fIN = 250kHz
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External Clock = 90MHz, VIN = 3.6VP-P, Highpass Filter Cutoff = 45kHz,
Lowpass Filter Cutoff = 300kHz
fIN = 50kHz
fIN = 250kHz
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Matching of Filter Phase
Filter Gain Either Channel External Clock = 90MHz, Highpass Filter Cutoff = 15kHz,
Gain = 0dB
Lowpass Filter Cutoff = 150kHz, VIN = 3.6VP-P
fIN = 7.5kHz
fIN = 15kHz
fIN = 50kHz
fIN = 150kHz
fIN = 450kHz
Matching of Filter Gain
Filter Phase Either
Channel
Matching of Filter Phase
External Clock = 90MHz, VIN = 3.6VP-P, Highpass Filter Cutoff = 15kHz,
Lowpass Filter Cutoff = 150kHz
fIN = 15kHz
fIN = 50kHz
fIN = 150kHz
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External Clock = 90MHz, VIN = 3.6VP-P, Highpass Filter Cutoff = 15kHz,
Lowpass Filter Cutoff = 150kHz
fIN = 16.5kHz
fIN = 125kHz
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External Clock = 90MHz, VIN = 3.6VP-P, Highpass Filter Cutoff = 15kHz,
Lowpass Filter Cutoff = 150kHz
fIN = 16.5kHz
fIN = 125kHz
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Filter Gain Either Channel External Clock = 90MHz, Highpass Filter Cutoff = 90kHz,
Gain = 0dB
Lowpass Filter Cutoff = 900kHz, VIN = 3.6VP-P
fIN = 45kHz
fIN = 90kHz
fIN = 300kHz
fIN = 900kHz
fIN = 2700kHz
Matching of Filter Gain
External Clock = 90MHz, Highpass Filter Cutoff = 90kHz,
Lowpass Filter Cutoff = 900kHz, VIN = 3.6VP-P
fIN = 90kHz
fIN = 300kHz
fIN = 900kHz
Filter Phase Either Chanel External Clock = 90MHz, VIN = 3.6VP-P, Highpass Filter Cutoff = 90kHz,
Lowpass Filter Cutoff = 900kHz
fIN = 100kHz
fIN = 750kHz
Matching of Filter Phase
Filter Cutoff Accuracy
when Self Clocked
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MIN
TYP
MAX
UNITS
125
–134
130
–130
134
–126
deg
deg
±2
±1.5
deg
deg
–30
–0.8
0.9
–1.3
–43
dB
dB
dB
dB
dB
±0.2
±0.2
±0.2
dB
dB
dB
146
–134
deg
deg
±2
±1
deg
deg
–27
–0.7
1.2
–0.5
–44
dB
dB
dB
dB
dB
±0.3
±0.6
±0.4
dB
dB
dB
145
–127
deg
deg
–1.6
0.4
–2.3
137
–142
–1.8
–0.1
–2.1
–32
–1.2
0.7
–1.9
–44
142
–138
–29
–1.2
0.6
–1.1
–45
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136
–136
141
–131
External Clock = 90MHz, VIN = 3.6VP-P, Highpass Filter Cutoff = 90kHz,
Lowpass Filter Cutoff = 900kHz
fIN = 100kHz
fIN = 750kHz
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±2
±1.5
deg
deg
CLKCNTL = 3V (Note 4)
RBIAS = 200k, Output Clock = 24.705MHz
RBIAS = 54.9k, Output Clock = 90MHz
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±3
±3
%
%
6602fa
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LTC6602
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. V+A = V+D = V+IN = 3V, VICM = VOCM = 1.5V, Gain = 0dB, lowpass cutoff =
300kHz, highpass cutoff = 45kHz, internal clocking with RBIAS = 54.9k unless otherwise noted.
PARAMETER
CONDITIONS
PGA Gain
Lowpass Cutoff = 150kHz, Highpass Filter Bypassed,
Measured at DC, 0.6V to 2.4V Each Output
Gain Setting = 0dB
Gain Setting = 12dB
Gain Setting = 24dB
Gain Setting = 30dB
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Lowpass Cutoff = 150kHz, Highpass Filter Bypassed,
Measured at DC, 0.6V to 2.4V Each Output
Gain Setting = 0dB
Gain Setting = 12dB
Gain Setting = 24dB
Gain Setting = 30dB
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PGA Gain Matching
Noise At 200kHz
MIN
TYP
MAX
UNITS
0.4
11.6
23.5
29.1
0.8
12
23.8
29.6
1.2
12.4
24.1
30.1
dB
dB
dB
dB
±0.2
±0.2
±0.3
±0.3
dB
dB
dB
dB
Voltage Noise Referred to the Input
Gain = 0dB
Gain = 12dB
Gain = 24dB
Gain = 30dB
–119
–131
–142
–146
dBm/Hz
dBm/Hz
dBm/Hz
dBm/Hz
Noise Bandwidth = 1.57MHz (Note 5), Referred to the Input
Gain = 0dB
Gain = 12dB
Gain = 24dB
Gain = 30dB
–62
–74
–85
–89
dBm
dBm
dBm
dBm
THD
VIN = 1.5VP-P, fIN = 100kHz
–75
dB
Input Impedance
Differential
Common Mode
16
20
kΩ
kΩ
VOS Differential
Differential Offset Voltage at Either Output
Differential Offset Voltage at Either Output HPF Bypassed, Lowest LPF Cutoff
Differential Offset Voltage at Either Output HPF Bypassed, Highest LPF Cutoff
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VOSCM
Common Mode Offset Voltage
VOCM = 1.5V, Supplies = 3V
VOSCM = VOUT-CM – VOCM
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Integrated Noise
CMR Differential
ΔVINCM /ΔVOUTDIFF
Common Mode Input from 0 to 3V
V+IN = 3V
Common Mode Input from 0 to 5V
V+IN = 5V
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±7
±10
±10
±15
±30
±30
mV
mV
mV
–40
±20
70
mV
75
95
dB
75
95
VOCM Pin Voltage
V+A = V+D = 3V, Pin 3 Open
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1.2
1.4
1.6
V
VOCM Pin Input
Impedance
V+A = V+D = 3V, Pin 3 Open
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300
400
700
Ω
Output Swing
Lowpass Cutoff = 150kHz, Highpass Filter Bypassed, Measured at DC
Source 1mA, VOUT High, Relative to V+A
Sink 1mA, VOUT Low, Relative to GND
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200
200
500
500
mV
mV
Lowpass Cutoff = 150kHz, Highpass Filter Bypassed
Sourcing
Sinking
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15
25
25
50
mA
mA
Internal Clock (RBIAS = 54.9k); Sum of the Currents into V+D, V+A, and
V+IN All Supplies Set to 3V
HPF = 15k, LPF = 150k
HPF = 45k, LPF = 300k
HPF = 90k, LPF = 900k
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65
100
105
80
125
130
mA
mA
mA
Short-Circuit Current
Supply Current
4
10
dB
6602fa
4
LTC6602
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. V+A = V+D = V+IN = 3V, VICM = VOCM = 1.5V, Gain = 0dB, lowpass cutoff =
300kHz, highpass cutoff = 45kHz, internal clocking with RBIAS = 54.9k unless otherwise noted.
PARAMETER
CONDITIONS
Supply Current,
Shutdown Mode
Sum of the Currents into V+D, V+A, and V+IN; All Supplies Set to 3V
Shutdown Via Serial Interface, Control Bit D1 = 1.
MIN
TYP
MAX
UNITS
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Supply Voltage
V+D, V+A Relative to GND
V+IN Relative to GND
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170
235
μA
2.7
2.7
3.6
5.5
V
V
PSR
V+D = V+A = V+IN, All from 2.7V to 3.6V
V+D = V+A = 3.0V, V+IN from 4.5V to 5.5V
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50
80
RBIAS Resistor Range
Clock Frequency Error ≤ ±3%, CLKCNTL = 3V
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54.9
RBIAS Pin Voltage
54.9k < RBIAS < 200k
Clock Frequency Drift
Over Temperature
RBIAS = 54.9k, CLKCNTL Pin Open
Clock Frequency Change
Over Supply
V+A, V+D from 2.7V to 3.6V, RBIAS = 54.9k, CLKCNTL Pin Open
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–0.6
0.1
0.6
%/V
Output Clock Duty Cycle
RBIAS = 54.9k
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25
50
75
%
CLKIO Pin High Level
Input Voltage
CLKCNTL = 0V (Note 6)
CLKIO Pin Low Level
Input Voltage
CLKCNTL = 0V (Note 6)
CLKIO Pin Input Current
CLKCNTL = 0V
CLKIO = 0V (Note 7)
CLKIO = V+D
60
95
dB
dB
200
1.17
V
40
ppm/ºC
V+D – 0.3
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kΩ
V
0.3
V
10
μA
μA
–1
CLKIO Pin High Level
Output Voltage
V+A = V+D = 3V, CLKCNTL = 3V
IOH = –1mA
IOH = –4mA
2.95
2.9
V
V
CLKIO Pin Low Level
Output Voltage
V+A = V+D = 3V, CLKCNTL = 3V
IOL = 1mA
IOL = 4mA
0.05
0.1
V
V
CLKIO Rise Time
V+A = V+D = CLKCNTL = 3V, 20%/80%, CLOAD = 5pF
0.3
ns
CLKIO Fall Time
V+A = V+D = CLKCNTL = 3V, 20%/80%, CLOAD = 5pF
0.3
ns
SER, MUTE
High Level Input Voltage
Pins 17, 20
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SER, MUTE
Low Level Input Voltage
Pins 17, 20
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SER, MUTE
Input Current
Pin 17 or Pin 20 = 0V (Note 7)
Pin 17 or Pin 20 = V+D
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–10
CLKCNTL High Level
Input Voltage
Pin 5
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V+D – 0.5
CLKCNTL Low Level
Input Voltage
Pin 5
CLKCNTL Input Current
CLKCNTL = 0V (Note 7)
CLKCNTL = V+D
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V+D – 0.3
–25
V
0.3
V
2
μA
μA
V
–15
15
0.5
V
25
μA
μA
6602fa
5
LTC6602
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. Specifications apply to pins 6, 9-11, 21 and 22.
Pin Programmable Control Mode Specifications
SYMBOL
PARAMETER
CONDITIONS
MIN
VIH
Digital Input High Voltage
Pins 6, 9-11, 21, 22
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VIL
Digital Input Low Voltage
Pins 6, 9-11, 21, 22
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IIN
Digital Input Current
Pins 6, 9-11, 21, 22 (Note 7)
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TYP
MAX
UNITS
V+D = 2.7V to 3.6V
2
V
–1
0.8
V
1
μA
Serial Port DC and Timing Specifications
SYMBOL
PARAMETER
CONDITIONS
MIN
VIH
Digital Input High Voltage
Pins 6, 9, 10
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VIL
Digital Input Low Voltage
Pins 6, 9, 10
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IIN
Digital Input Current
Pins 6, 9, 10 (Note 7)
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–1
VOH
Digital Output High Voltage
Pins 11, 21 Sourcing 500μA
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VSUPPLY -0.3
TYP
MAX
UNITS
V+D = 2.7V to 3.6V
2
V
0.8
V
1
μA
V
VOL
Digital Output Low Voltage
Pins 11, 21 Sinking 500μA
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t1
SDI Valid to SCLK Setup
(Note 6)
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60
ns
t2
SDI Valid to SCLK Hold
(Note 6)
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0
ns
t3
SCLK Low
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100
ns
t4
SCLK High
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100
ns
t5
CS Pulse Width
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60
ns
t6
LSB SCLK to CS
(Note 6)
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60
ns
t7
CS Low to SCLK
(Note 6)
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30
ns
t8
SDO Output Delay
CL = 15pF
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t9
SCLK Low to CS Low
(Note 6)
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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: LTC6602C and LTC6602I are guaranteed functional over the
operating temperature range of –40°C to 85°C.
Note 3: LTC6602C is guaranteed to meet specified performance from
0°C to 70°C. The LTC6602C is designed, characterized and expected to
meet specified performance from –40°C to 85°C but is not tested or QA
sampled at these temperatures. The LTC6602I is guaranteed to meet the
specified performance limits from –40°C to 85°C.
0.3
125
0
V
ns
ns
Note 4: This test measures the internal oscillator accuracy (deviation from
the fCLK equation). Variations in the internal oscillator frequency cause
variations in the filter cutoff frequency. See the “Applications Information”
section.
Note 5: 1.57MHz is the equivalent noise bandwidth of a 1MHz 1st order
RC lowpass filter.
Note 6: Guaranteed by design, not subject to test.
Note 7: To conform to the Logic IC standard, current out of a pin is
arbitrarily given a negative value.
6602fa
6
LTC6602
TYPICAL PERFORMANCE CHARACTERISTICS
Distortion vs Input Frequency
–10
–20
–30
TA = 25°C, VS = 3V, DIFFERENTIAL INPUT,
VIN = 1.5VP-P, 12.4-82.4kHz BPF, RBIAS = 200k
45kHz-300kHz BPF, RBIAS = 54.9k, GAIN = 0dB
–75
HD3
12kHz-82kHz BPF
HD2
45kHz-300kHz BPF
–80
HD2
12kHz-82kHz BPF
–50 45kHz-300kHz BPF
10k
100k
1M
FREQUENCY (Hz)
–90
10M
0
50
100
150
200
250
INPUT FREQUENCY (kHz)
–70
DISTORTION (dBc)
DISTORTION (dBc)
HD3
–80
6
12
18
GAIN (dB)
24
HD2
–90
30
15
30
45
60
75
HIGHPASS CUTOFF FREQUENCY (kHz)
0.05
–40°C
25°C
HD3
HD2
–90
90
85°C
–0.05
2.7 2.8 2.9 3.0 3.1 3.2 3.3 3.4 3.5 3.6
SUPPLY VOLTAGE (V)
6602 G07
TA = 25°C
VS = 3V
fIN = 100kHz
DIFFERENTIAL INPUT, VIN = 1.5VP-P
RBIAS = 54.9k
fHP = 45kHz
GAIN = 0dB
0
150
300
450
600
750
LOWPASS CUTOFF FREQUENCY (kHz)
Common Mode Rejection
120
VS = 3V
0.3 RBIAS = 54.9k
45kHz-300kHz BPF
GAIN = 0dB
0.2
110
0.1
5 TYPICAL UNITS
–0.1
–0.2
–0.3
–0.4
–40
–20
0
20
40
60
TEMPERATURE (°C)
900
6602 G06
0.4
0.0
6
–80
Filter Cutoff Accuracy
vs Temperature
FILTER CUTOFF FREQUENCY DEVIATION (%)
FILTER CUTOFF FREQUENCY DEVIATION (%)
Filter Cutoff Accuracy
vs Supply Voltage
5
–75
6602 G05
6602 G04
RBIAS = 54.9k
45kHz-300kHz BPF
GAIN = 0dB
2
3
4
OUTPUT VOLTAGE (VP-P)
–70
–85
0
1
66062 G03
–85
–85
0
0
Distortion vs Lowpass
Cutoff Frequency
TA = 25°C
VS = 3V
fIN = 100kHz
DIFFERENTIAL INPUT, VIN = 1.5VP-P
RBIAS = 54.9k
fLP = 300kHz
GAIN = 0dB
HD3
–75
HD2
0.00
–100
300
66062 G02
–70
–80
HD3
–90
Distortion vs Highpass
Cutoff Frequency
TA = 25°C
VS = 3V
fIN = 100kHz
DIFFERENTIAL INPUT, VOUT = 1.5VP-P
–75 R
BIAS = 54.9k
45kHz-300kHz BPF
HD2
–80
DISTORTION (dBc)
1k
Distortion vs Gain
0.10
–70
HD3
45kHz-300kHz BPF
6602 G01
–90
TA = 25°C
V = 3V
–40 f S = 100kHz
IN
DIFFERENTIAL INPUT
–50 RBIAS = 54.9k
RBIAS = 45kHz-300kHz BPF
–60 GAIN = 0dB
–85
–40
–60
Distortion vs Output Voltage
–30
80
6602 G08
COMMON MODE REJECTION (dB)
GAIN (dB)
15kHz-150kHz BPF
90kHz-900kHz BPF
DISTORTION (dBc)
TA = 25°C
VS = 3V
EXTERNAL CLOCK
RBIAS = 54.9k
0 GAIN
= 0dB
10
–70
DISTORTION (dBc)
Gain vs Frequency
20
CMR = ΔVIN-CM /ΔVOUT-DIFF
100
90
80
70
GAIN = 0dB
60
GAIN = 12dB
TA = 25°C
50 V = 3V
S
GAIN = 24dB
40 VIN-CM = 0V
GAIN = 30dB
ΔVIN-CM = 1.25VP-P
30 RBIAS = 54.9k
45kHz-300kHz BPF
20
1k
10k
100k
1M
10M
FREQUENCY (Hz)
6602 G09
6602fa
7
LTC6602
TYPICAL PERFORMANCE CHARACTERISTICS
Common Mode Rejection
100
GAIN = 12dB
GAIN = 0dB
90
80
70 GAIN = 24dB
GAIN = 30dB
60
TA = 25°C
50 V = 3V
S
40 VIN-CM = 0V
ΔVIN-CM = 1.25VP-P
30 RBIAS = 54.9k
15kHz-150kHz BPF
20
1k
10k
100k
FREQUENCY (Hz)
120
TA = 25°C, VS = 3V,
110 VIN-CM = 0V, ΔVIN-CM = 1.25VP-P,
RBIAS = 54.9k, 90kHz-900kHz BPF
100
110
100
90
80
70
GAIN = 0dB
60
50
GAIN = 24dB
GAIN = 12dB
30
CMR = ΔVIN-CM /ΔVOUT-DIFF
20
10k
100k
1M
FREQUENCY (Hz)
10M
GAIN = 24dB
CMRR (dB)
CMRR (dB)
90
GAIN = 0dB
60
GAIN = 12dB
50
40
40
TA = 25°C, VS = 3V,
30 VIN-CM = 0V, ΔVIN-CM = 1.25VP-P,
RBIAS = 54.9k, 15kHz-150kHz BPF
20
1k
10k
100k
FREQUENCY (Hz)
48
GAIN = 24dB
60
50
GAIN = 0dB
GAIN = 0dB
40
20
10k
1M
100k
1M
FREQUENCY (Hz)
GAIN = 0dB
TA = 25°C
VS = 3V
f1 = fC –5kHz
f2 = fC +5kHz
VOUT = 6dBm PER TONE
FOR 2-TONE TEST
RBIAS = 54.9k
15kHz-150kHz BPF
42
40
0
20 40 60 80 100 120 140 160
CENTER SIGNAL FREQUENCY, fC (kHz)
6602 G16
OIP3 (dBm)
OIP3 (dBm)
GAIN = 24dB
50 100 150 200 250 300 350
CENTER SIGNAL FREQUENCY, fC (kHz)
OIP3 vs Temperature
50
48
TA = 25°C, VS = 3V
f1 = fC –10kHz, f2 = fC +10kHz
VOUT = 6dBm PER TONE
46 FOR 2-TONE TEST
RBIAS = 54.9k
90kHz-900kHz BPF
44
0
6602 G15
OIP3 vs Average Signal
Frequency, fC
GAIN = 12dB
44
38
10M
6602 G14
GAIN = 30dB
46
GAIN = 30dB
GAIN = 12dB
42
30
OIP3 vs Average Signal
Frequency, fC
48
TA = 25°C
VS = 3V
f1 = fC –5kHz, f2 = fC +5kHz
46 V
OUT = 6dBm PER TONE FOR 2-TONE TEST
RBIAS = 54.9k
45kHz-300kHz BPF
44
GAIN = 24dB
GAIN = 30dB
6602 G13
38
OIP3 vs Average Signal
Frequency, fC
OIP3 (dBm)
GAIN = 30dB
TA = 25°C
110 VS = 3V
VIN-CM = 0V
100 ΔV
IN-CM = 1.25VP-P
90 RBIAS = 54.9k
90kHz-900kHz BPF
80
GAIN = 12dB
70
10M
6602 G12
120
120
70
GAIN = 0dB
TA = 25°C, VS = 3V,
30 VIN-CM = 0V, ΔVIN-CM = 1.25VP-P,
RBIAS = 54.9k, 45kHz-300kHz BPF
20
1k
10k
100k
1M
FREQUENCY (Hz)
GAIN = 30dB
Common Mode Rejection Ratio
80
GAIN = 12dB
60
6602 G11
Common Mode Rejection Ratio
100
70
40
6602 G10
110
GAIN = 24dB
80
50
40
1M
GAIN = 30dB
90
GAIN = 12dB
OIP3 (dBm)
COMMON MODE REJECTION (dB)
COMMON MODE REJECTION (dB)
CMR = ΔVIN-CM /ΔVOUT-DIFF
110
Common Mode Rejection Ratio
Common Mode Rejection
120
CMRR (dB)
120
42
VS = 3V
VOUT = 6dBm PER TONE
FOR 2-TONE TEST
48 RBIAS = 54.9k
GAIN = 30dB
fIN = 95kHz, 105kHz
15kHz-150kHz BPF
46
44
fIN = 145kHz, 155kHz
45kHz-300kHz BPF
GAIN = 24dB
40
42
GAIN = 30dB
GAIN = 0dB
38
0 100 200 300 400 500 600 700 800 900 1000
CENTER SIGNAL FREQUENCY, fC (kHz)
6602 G17
fIN = 590kHz, 610kHz
90kHz-900kHz BPF
40
–40–30–20–10 0 10 20 30 40 50 60 70 80 90
TEMPERATURE (°C)
6602 G18
6602fa
8
LTC6602
TYPICAL PERFORMANCE CHARACTERISTICS
TA = 25°C
VS = 3V
RBIAS = 54.9k
105
SUPPLY CURRENT (mA)
OUTPUT IMPEDANCE (Ω)
Supply Current vs Supply Voltage
110
10
15kHz-150kHz BPF
90kHz-900kHz BPF
1 900kHz LPF
Supply Current vs Temperature
120
CLKCNTL PIN FLOATING
RBIAS = 54.9k
45kHz-300kHz BPF
GAIN = 0dB
90kHz-900kHz BPF
100
SUPPLY CURRENT (mA)
Output Impedance vs Frequency
100
85°C
100
25°C
–40°C
95
1k
10k
100k
1M
FREQUENCY (Hz)
10M
80
15kHz-150kHz BPF
60
40
90
2.7 2.8 2.9 3.0 3.1 3.2 3.3 3.4 3.5 3.6
SUPPLY VOLTAGE (V)
VS = 3V
20 CLKCNTL PIN FLOATING
RBIAS = 54.9k
GAIN = 0dB
0
–40–30–20–10 0 10 20 30 40 50 60 70 80 90
TEMPERATURE (°C)
6602 G20
6602 G21
45kHz-300kHz BPF
0.1
45kHz-300kHz BPF
6602 G19
RBIAS Pin Voltage vs IRBIAS
Clock Output Operating at 90MHz
RBIAS PIN VOLTAGE (V)
1.25
1V/DIV
0V
1.20
1.15
1.10
6602 G22
2.5ns/DIV
TA = 25°C
VS = 3V
0
5
10
15
IRBIAS (μA)
20
25
6602 G23
Input Referred Noise Density
GAIN = 0dB
INTEGRATED
NOISE = 186.5μVRMS
VOLTAGE NOISE DENSITY (nV/√Hz)
VOLTAGE NOISE DENSITY (nV/√Hz)
1000
GAIN = 12dB
INTEGRATED NOISE
= 47.1μVRMS
100
10
1
GAIN = 30dB
INTEGRATED
NOISE = 7.5μVRMS
1k
GAIN = 24dB
INTEGRATED
NOISE = 12.6μVRMS
10k
100k
FREQUENCY (Hz)
TA = 25°C, VS = 3V, EXTERNAL CLOCK
RBIAS = 54.9k, 45kHz-300kHz BPF
INTEGRATED NOISE BW = 1.57MHz
1M
Input Referred Noise Density
GAIN = 0dB INTEGRATED NOISE = 189μVRMS
100
GAIN = 12dB
INTEGRATED
NOISE= 47.8μVRMS
10
GAIN = 24dB
INTEGRATED NOISE = 12.5μVRMS
1
GAIN = 30dB INTEGRATED NOISE = 7.2μVRMS
1k
10k
100k
FREQUENCY (Hz)
6602 G24
TA = 25°C, VS = 3V, EXTERNAL CLOCK
RBIAS = 54.9k, 15kHz-150kHz BPF
INTERNAL NOISE BW = 400kHz
1000
VOLTAGE NOISE DENSITY (nV/√Hz)
Input Referred Noise Density
1000
1M
6602 G25
GAIN = 0dB INTEGRATED NOISE = 304.2μVRMS
GAIN = 12dB INTEGRATED NOISE
= 77.6μVRMS
100
10
GAIN = 24dB
INTEGRATED
NOISE = 20.7μVRMS
GAIN = 30dB
INTEGRATED NOISE = 17.5μVRMS
1
10k
100k
1M
FREQUENCY (Hz)
TA = 25°C, VS = 3V, EXTERNAL CLOCK
RBIAS = 54.9k, 90kHz-900kHz BPF
INTERNAL NOISE BW = 2.5MHz
10M
6602 G26
6602fa
9
LTC6602
PIN FUNCTIONS
V+IN (Pin 1): Input Voltage Supply (2.7V ≤ V ≤ 5.5V). This
supply must be kept free from noise and ripple. It should
be bypassed directly to a ground plane with a 0.1μF capacitor unless it is tied to V+A (Pin 2). The bypass should
be as close as possible to the IC, but is not as critical as
the bypassing of V+A and V+D (Pin16).
V+A (Pin 2): Analog Voltage Supply (2.7V ≤ V ≤ 3.6V). This
supply must be kept free from noise and ripple. It should be
bypassed directly to a ground plane with a 0.1μF capacitor.
The bypass should be as close as possible to the IC.
VOCM (Pin 3): Output common mode voltage reference. If
floated, an internal resistive divider sets the voltage on this
pin to half the supply voltage (typically 1.5V), maximizing
the dynamic range of the filter. If this pin is floated, it must
be bypassed with a quality 0.1μF capacitor to ground.
This pin has a typical input impedance of 400Ω and may
be overdriven. Driving this pin to a voltage other than the
default value will reduce the signal range the filter can
handle before clipping.
RBIAS (Pin 4): Oscillator Frequency-Setting Resistor Input.
The value of the resistor connected between this pin and
ground determines the frequency of the master oscillator,
and sets the bias currents for the filter networks. The voltage on this pin is held by the LTC6602 to approximately
1.17V. For best performance, use a precision metal film
resistor with a value between 54.9k and 200k and limit the
capacitance on this pin to less than 10pF. This resistor is
necessary even if an external clock is used.
CLKCNTL (Pin 5): Clock Control Input. This three-state
input selects the function of CLKIO (Pin 15). Tying the
CLKCNTL pin to ground allows the CLKIO pin to be driven
by an external clock (CLKIO is the master clock input).
If the CLKCNTL pin is floated, the internal oscillator is
enabled, but the master clock is not present at the CLKIO
pin (CLKIO is a no-connect). If the CLKCNTL pin is tied
to V+D (Pin 16), the internal oscillator is enabled and the
master clock is present at the CLKIO pin (CLKIO is the
master clock output). To detect a floating CLKCNTL pin,
the LTC6602 attempts to pull the pin toward mid-supply.
This is realized with two internal current sources, one tied
to V+D and CLKCNTL and the other one tied to ground
and CLKCNTL. Therefore, driving the CLKCNTL pin high
requires sourcing approximately 15μA. Likewise, driving
the CLKCNTL pin low requires sinking 15μA. When the
CLKCNTL pin is floated, preferably it should be bypassed
by a 1nF capacitor to ground or it should be surrounded
by a ground shield to prevent excessive coupling from
other PCB traces.
LPF1(CS) (Pin 6): Logic Input. When in pin programmable
control mode, this pin is the MSB of the lowpass cutoff
frequency control code; in serial control mode, this pin is
the chip select input (active low).
+INB, –INB (Pins 7, 8): Channel B differential inputs.
The input range and input resistance are described in the
Applications Information section. Input voltages which
exceed V+IN (Pin 1) should be avoided.
LPF0(SCLK) (Pin 9): Logic Input. When in pin programmable control mode, this pin is the LSB of the lowpass
cutoff frequency control code; in serial control mode, this
pin is the clock of the serial interface.
HPF1(SDI) (Pin 10): Logic Input. When in pin programmable control mode, this pin is the MSB of the highpass
cutoff frequency control code; in serial control mode, this
pin is the serial data input.
HPF0(SDO) (Pin 11): Logic Input. When in pin programmable control mode, this pin is the LSB of the highpass
cutoff frequency control code; in serial control mode, this
pin is the serial data output.
–OUTB, +OUTB (Pins 12, 13): Channel B differential filter
outputs. These pins can drive 1k and/or 50pF loads. For
larger capacitive loads, an external 100Ω series resistor
is recommended for each output. The common mode
voltage of the filter outputs is the same as the voltage at
VOCM (Pin 3).
GND (Pin 14): Ground. Connect to a ground plane for
best performance.
6602fa
10
LTC6602
PIN FUNCTIONS
CLKIO (Pin 15): When CLKCNTL (Pin 5) is tied to ground,
CLKIO is the master clock input. When CLKCNTL is floated,
CLKIO is pulled to ground by a weak, 5μA pulldown. When
CLKCNTL is tied to V+D (Pin 16), CLKIO is the master clock
output. When configured as a clock output, this pin can
drive 1k and/or 5pF loads. Heavier loads may cause inaccuracies due to supply bounce at high frequencies.
V+D (Pin 16): Digital Voltage Supply (2.7V ≤ V ≤ 3.6V).
This supply must be kept free from noise and ripple. It
should be bypassed directly to a ground plane with a 0.1μF
capacitor. The bypass should be as close as possible to
the IC.
larger capacitive loads, an external 100Ω series resistor
is recommended for each output. The common mode
voltage of the filter outputs is the same as the voltage at
VOCM (Pin 3).
MUTE (Pin 20): MUTEX input. Drive to ground to disconnect and mute the inputs. Float or drive to V+D (Pin 16)
for normal operation.
GAIN0(D0) (Pin 21): Logic Input. When in pin programmable control mode, this pin is the LSB of the gain control
code; in serial control mode, this pin is the LSB of the
serial control register, an output.
SER (Pin 17): Interface Selection Input. When tied to V+D
(Pin 16), the interface is in pin programmable control mode,
i.e. the filter gain and cutoff frequencies are programmed
by the GAIN1, GAIN0, HPF1, HPF0, LPF1 and LPF0 pin
connections. When SER is tied to ground, the filter gain,
the filter cutoff frequencies and shutdown mode are programmed by the serial interface.
GAIN1 (Pin 22): Logic Input. When in pin programmable
control mode, this pin is the MSB of the gain control code;
in serial control mode, this pin is a no-connect.
–OUTA, +OUTA (Pins 18, 19): Channel A differential filter
outputs. These pins can drive 1k and/or 50pF loads. For
Exposed Pad (Pin 25): Ground. The Exposed Pad must
be soldered to PCB.
–INA, +INA (Pins 23, 24): Channel A differential inputs.
The input range and input resistance are described in the
Applications Information section. Input voltage levels can
range from GND to the V+IN supply rail.
6602fa
11
LTC6602
BLOCK DIAGRAM
+INA
–INA
GAIN1
GAIN0(D0)
MUTE
+OUTA
24
23
22
21
20
19
V+IN 1
18 –OUTA
CHANNEL A
PGA
LPF
HPF
17 SER
V+A 2
CONTROL
BIAS
CLK
VDDA
1.6k
VOCM 3
16 V+D
1.6k
GND
CONTROL
LOGIC
BIAS/OSC
CLOCK
GENERATOR
RBIAS 4
15 CLKIO
BIAS
CLKCNTL 5
PGA
CONTROL
CLK
LPF
HPF
14 GND
CHANNEL B
LPF1(CS) 6
13 +OUTB
7
8
9
10
11
12
+INB
–INB
LPF0(SCLK)
HPF1(SDI)
HPF0(SDO)
–OUTB
6602 BD
6602fa
12
LTC6602
TIMING DIAGRAM
Timing Diagram of the Serial Interface
t4
t1
t2
t6
t3
t7
SCLK
t9
D3
SDI
D2
D1
D0
D7 • • • • D4
D3
t5
CS
t8
SDO
D4
PREVIOUS BYTE
D3
D2
D1
D0
D7 • • • • D4
CURRENT BYTE
D3
6602 TD
6602fa
13
LTC6602
APPLICATIONS INFORMATION
Theory of Operation (Refer to Block Diagram)
Pin Programmable Interface
The LTC6602 features two matched filter channels, each
containing gain control, lowpass, and highpass networks
that are controlled by a single control block and clocked by
a single clock generator. The gain, lowpass and highpass
sections can be independently programmed. The two
channels are not independent, i.e. if the gain is set to 24dB,
then both channels have a gain of 24dB. The filter can also
be programmed to bypass the highpass filter networks,
giving a lowpass response. The filter can be clocked with
an external clock source, or using the internal oscillator. A
resistor connected to the RBIAS pin sets the bias currents
for the filter networks and the internal oscillator frequency
(unless driven by an external clock). Altering the clock
frequency changes the filter bandwidths. This allows the
filters to be “tuned” to many different bandwidths.
As shown in Figure 1, connecting SER to V+D allows the
filter to be directly controlled through the pin programmable
control lines GAIN1, GAIN0, HPF1, HPF0, LPF1 and LPF0.
The HPF0(SDO) and GAIN0(D0) pins are bidirectional (inputs in pin programmable control mode, outputs in serial
mode). In pin programmable control mode, the voltages
at HPF0(SDO) and GAIN0(D0) cannot exceed V+D; otherwise, large currents can be injected to V+D through the
internal diodes (see Figure 2). Connecting a 10k resistor
at the HPF0(SDO) and GAIN0(D0) pins (see Figure 1) is
recommended for current limiting, to less than 10mA. SER
has an internal pull-up to V+D. None of the logic inputs
have an internal pull-up or pull-down.
3.3V
3.3V
LTC6602
0.1μF
+
V+IN
V+A
V+A
V+D
V+D
+INA
+OUTA
VIN
–
LTC6602
0.1μF
V+IN
–INA
–OUTA
+
+
VOUT
VIN
+INA
+
VOUT
–
–
+OUTA
–INA
SER
–OUTA
–
SER
LPF1
LPF1(CS)
LPF1(CS)
LPF0
LPF0(SCLK)
LPF0(SCLK)
HPF1
HPF1(SDI)
μP
HPF0(SDO)
HPF0
10k
HPF0(SDO)
GAIN1
GAIN1
GAIN1
GAIN0
GAIN0(D0)
10k
GND
LOWPASS CUTOFF = 900kHz (fCLK = 90MHz)
HIGHPASS CUTOFF = 90kHz (fCLK = 90MHz)
GAIN = 16
HPF1(SDI)
GAIN0(D0)
GND
GAIN, BANDWIDTHS ARE SET BY MICROPROCESSOR.
10k RESISTORS ON HPF0(SDO) AND GAIN0(D0)
PROTECT THE DEVICE IF VHPF0 > V+D OR
VGAIN0 > V+D
6602 F01
Figure 1. Filter in Pin Programmable Control Mode
6602fa
14
LTC6602
APPLICATIONS INFORMATION
V+D
SHUTDOWN
6-BIT GAIN, BW
CONTROL CODE
OUT
CS
8-BIT LATCH
HPF0(SDO)
Q0 Q1 Q2 Q3 Q4 Q5 Q6 Q7
8-BIT
SHIFT-REGISTER
DIN
(INTERNAL
NODE)
6602 F02
SDO
SCLK
6602 F03
Figure 2. Bidirectional Design of
HPFO(SDO) and GAIN0(D0) Pins
Figure 3. Diagram of Serial Interface (MSB First Out)
3.3V
3.3V
0.1μF
V+IN
+
LTC6602
#1
0.1μF
V+A
V+A
V+D
V+D
+
+
+OUTA
+INA
VIN1
+OUTA
+
–INA
–OUTA
–
VOUT2
–
–
–OUTA
–INA
+INA
VIN2
VOUT1
–
LTC6602
#2
V+IN
SER
SER
LPF1(CS)
LPF1(CS)
LPF1(CS)
SCLK
μP
SDI
LPF0(SCLK)
GAIN0(D0)
HPF1(SDI)
HPF0(SDO)
OUT1
GND
LPF0(SCLK)
GAIN0(D0)
OUT2
HPF1(SDI)
HPF0(SDO)
SDO
GND
SCLK
SDI
D15
D11
D10
D9
D8
GAIN, BW CONTROL WORD FOR #2 SHUTDOWN FOR #2
D7
D3
D2
D1
D0
GAIN, BW CONTROL WORD FOR #1 SHUTDOWN FOR #1
CS
6602 F04
Figure 4. Two Filters in a Daisy Chain
Serial Control Register Definition
D7
D6
D5
D4
D3
D2
D1
D0
GAIN0
GAIN1
LPF0
LPF1
HPF0
HPF1
SHDN
OUT
6602fa
15
LTC6602
APPLICATIONS INFORMATION
Serial Interface
Self-Clocking Operation
Connecting SER to ground allows the filter to be controlled
through the SPI serial interface. When CS is low, the serial
data on SDI is shifted into an 8-bit shift-register on the
rising edge of the clock (SCLK), with the MSB transferred
first (see Figure 3). Serial data on SDO is shifted out on
the clock’s falling edge. A high CS will load the 8 bits of
the shift-register into an 8-bit D-latch, which is the serial
control register. The clock is disabled internally when
CS is pulled high. Note: SCLK must be low before CS is
pulled low to avoid an extra internal clock pulse. SDO is
always active in serial mode (never tri-stated) and cannot
be “wire-or’ed” to other SPI outputs. In addition, SDO is
not forced to zero when CS is pulled high.
The LTC6602 features a unique internal oscillator which sets
the filter cutoff frequency using a single external resistor
connected to the RBIAS pin. The clock frequency is determined by the following simple formula (see Figure 5):
GAIN1 and GAIN0 are the gain control bits (register bits
D6 and D7 when in serial mode). Their function is shown
in Table 1. In serial mode, register bit D1 can be set to
‘1’ to put the device into a low power shutdown mode.
Register bit D0 is a general purpose output (Pin 21) when
in serial mode.
Table 1. Gain Control
GAIN 1
GAIN 0
PASSBAND GAIN
(dB)
0
0
0
0
1
12
1
0
24
1
1
30
Note: RBIAS ≤ 200k.
200
175
150
RBIAS (kΩ)
An LTC6602 may be daisy chained with other LTC6602s
or other devices having serial interfaces. Daisy chaining is accomplished by connecting the SDO of the lead
chip to the SDI of the next chip, while SCLK and CS
remain common to all chips in the daisy chain. The serial data is clocked to all the chips then the CS signal
is pulled high to update all of them simultaneously.
Figure 4 shows an example of two LTC6602s in a daisy
chained SPI configuration.
fCLK = 494.1MHz • 10k/RBIAS
125
100
75
50
20
30
40
50
60
70
80
DESIRED CLOCK FREQUENCY (MHz)
90
6602 F05
Figure 5. RBIAS vs Desired Clock Frequency
The design is optimized for V+A, V+D = 3V, fCLK = 90MHz,
where the filter cutoff frequency error is typically <3%
when a 0.1% external 54.9k resistor is used. With different resistor values and cutoff frequency control settings
(HPF1, HPF0, LPF1 and LPF0), the highpass and lowpass
cutoff frequencies can be accurately varied from 4.1175kHz
to 90kHz and from 41.175kHz to 900kHz, respectively.
Table 2 summarizes the cutoff frequencies that can be
obtained with an external resistor (RBIAS) value of 54.9k.
Note that the cutoff frequencies scale with the clock frequency. For example, if HPF1, HPF0, LPF1 and LPF0 are
all equal to zero, and RBIAS is increased from 54.9k to
200k, fCLK will decrease from 90MHz to 24.705MHz, the
lowpass cutoff frequency will be reduced from 150kHz
to 41.175kHz, and the highpass cutoff frequency will be
reduced from 15kHz to 4.1175Hz. The cutoff frequencies
that can be obtained with an external resistor value of 200k
6602fa
16
LTC6602
APPLICATIONS INFORMATION
are shown in Table 3. When the LTC6602 is programmed
for the lowest lowpass cutoff frequency (LPF1, LPF0 = ‘0’),
the power is automatically reduced by about 35%.
Table 2. Cutoff Frequency Control, RBIAS = 54.9k, fCLK = 90MHz
LPF1
LPF0
Lowpass
BW (kHz)
HPF1
HPF0
Highpass
BW (kHz)
0
0
150
0
0
15
0
1
300
0
1
45
1
0
900
1
0
90
1
1
900
1
1
Bypass HPF
LPF1
LPF0
Lowpass
BW (kHz)
HPF1
HPF0
Highpass
BW (kHz)
0
0
41.175
0
0
4.1175
0
1
82.35
0
1
12.3525
1
0
247.05
1
0
24.705
1
1
247.05
1
1
Bypass HPF
The following graphs show a few of the possible combinations of highpass and lowpass filters.
Gain and Group Delay vs Frequency
(45kHz to 300kHz Bandpass Response)
Gain and Group Delay vs Frequency
(15kHz to 150kHz Bandpass Response)
40
40
20
GAIN = 30dB
GAIN = 24dB 18
GAIN = 0dB
12
0
–10
10
–20
8
–30
6
–40
4
–40
2
–50
0
10M
–60
GROUP
DELAY
–50
–60
1k
10k
100k
1M
FREQUENCY (Hz)
60
GAIN = 30dB
48
GAIN = 12dB
42
30
–20
24
–30
18
12
GROUP
DELAY
1k
10k
100k
FREQUENCY (Hz)
20
GAIN (dB)
GAIN = 12dB
GAIN = 0dB
6
–10
5
–20
4
–30
3
–40
–50
–60
10k
2
GROUP
DELAY
100k
1M
FREQUENCY (Hz)
1
0
10M
6602 G30
1.0
30
GAIN = 30dB
0.9
20
GAIN = 24dB
0.8
10
GAIN = 12dB
0.7
0
–10
GAIN = 0dB
GROUP DELAY
0.6
0.5
–20
0.4
–30
0.3
TA = 25°C
VS = 3V
–50 EXTERNAL CLOCK
RBIAS = 54.9k
–60
1k
10k
100k
1M
FREQUENCY (Hz)
–40
GROUP DELAY (μs)
0
GAIN = 24dB
40
GROUP DELAY (μs)
10
0
1M
Gain and Group Delay vs Frequency
(900kHz Lowpass Response)
GAIN (dB)
30
10
TA = 25°C
VS = 3V 9
EXTERNAL
CLOCK 8
RBIAS = 54.9k 7
6
6602 G29
Gain and Group Delay vs Frequency
(90kHz to 900kHz Bandpass Response)
GAIN = 30dB
36
GAIN = 0dB
–10
6602 G28
40
54
GAIN = 24dB
GROUP DELAY (μs)
14
GAIN (dB)
GAIN = 12dB
0
TA = 25°C
30 VS = 3V
EXTERNAL
20 CLOCK
10 RBIAS = 54.9k
16
GROUP DELAY (μs)
TA = 25°C
30 VS = 3V
EXTERNAL
20 CLOCK
10 RBIAS = 54.9k
GAIN (dB)
Table 3. Cutoff Frequency Control, RBIAS = 200k, fCLK = 24.705MHz
0.2
0.1
0.0
10M
6602 G28
6602fa
17
LTC6602
APPLICATIONS INFORMATION
Preserving Oscillator Accuracy
The oscillator is sensitive to transients on the positive
supply. The IC should be soldered to the PC board and
the PCB layout should include a 0.1μF ceramic capacitor
between V+A (Pin 2) and ground, as close as possible to
the IC to minimize inductance. The PCB layout should also
include an additional 0.1μF ceramic capacitor between
V+D (Pin 16) and ground. Avoid parasitic capacitance on
RBIAS (Pin 4) and avoid routing noisy signals near RBIAS.
Use a ground plane connected to Pin 14 and the Exposed
Pad (Pin 25).
Alternative Methods of Setting the Clock Frequency of
the LTC6602
The oscillator may be programmed by any method that
sinks a current out of the RBIAS pin. The circuit in Figure 6
sets the clock frequency by using a programmable current
source and in the expression for fCLK, the resistor RBIAS
is replaced by the ratio of 1.17V/ICONTROL. Because the
voltage of the RBIAS pin is approximately 1.17V ±5%, the
Figure 6 circuit is less accurate than if a resistor controls
the clock frequency.
Figure 7 shows the LTC6602’s oscillator configured as
a VCO. A voltage source is connected in series with the
RBIAS resistor. The clock frequency, fCLK, will vary with
VCONTROL. Again, this circuit decouples the relationship
between the current out of the RBIAS pin and the voltage
of the RBIAS pin; the frequency accuracy will be degraded.
The clock frequency, however, will increase monotonically
with decreasing VCONTROL.
Operation Using an External Clock
The LTC6602 may be clocked by an external oscillator
for tighter bandwidth control by pulling CLKCNTL (Pin 5)
to ground and driving a clock into CLKIO (Pin 15). If an
external clock is used, the RBIAS resistor is still necessary.
The value of RBIAS must be no larger than the value that
would be required for using the internal oscillator. For
example, a 100k resistor would program the internal oscillator for 49.41MHz, so an external oscillator frequency of
49.41MHz would require an RBIAS resistance of no more
than 100k. If the value of RBIAS is too large, the filters will
not receive a large enough bias current, possibly causing
errors due to insufficient settling.
RBIAS
RBIAS
RBIAS
ICONTROL
VCONTROL
fCLK = 10k • (494.1MHz/1.17V) • ICONTROL(A)
6602 F06
Figure 6. Current Controlled Clock Frequency
+
–
fCLK = 494.1MHz • (10k/RBIAS) • (1 – VCONTROL/1.17V)
6602 F07
Figure 7. Voltage Controlled Clock Frequency
6602fa
18
LTC6602
APPLICATIONS INFORMATION
–70
TA = 25°C
fIN = 100kHz
DIFFERENTIAL INPUT, VIN = 1.5VP-P
–75 RBIAS = 54.9k
45kHz-300kHz BPF
GAIN = 0dB
DISTORTION (dBc)
DISTORTION (dBc)
–70
HD3
–80
HD2
–85
–90
TA = 25°C
fIN = 100kHz
DIFFERENTIAL INPUT, VIN = 1.5VP-P
–75 RBIAS = 54.9k
45kHz-300kHz BPF
GAIN = 0dB
HD3
–80
HD2
–85
0
0.5
1.0
1.5
2.0
2.5
COMMON MODE INPUT VOLTAGE (V)
–90
3.0
0
1
2
3
4
COMMON MODE INPUT VOLTAGE (V)
6602 F08
Figure 8. Distortion vs Common Mode Input Voltage (3V)
Input Common Mode and Differential Voltage Range
The input signal range extends from zero to the V+IN supply voltage. This input supply can be tied to V+A and V+D,
or driven up to 5.5V for increased input common mode
voltage range. Figures 8 and 9 show the distortion of the
filter versus common mode input voltage with a 1.5VP-P
differential input signal.
For best performance, the inputs should be driven differentially. For single ended signals, connect the unused
input to VOCM (Pin 3) or to a quiet DC reference voltage.
To achieve the best distortion performance, the input
signal should be centered around the DC voltage of the
unused input.
Refer to the Typical Performance Characteristics section
to estimate the distortion for a given input level.
Dynamic Input Impedance
The unique input sampling structure of the LTC6602 has a
dynamic input impedance which depends on the configuration and the clock frequency. This dynamic input impedance
has both a differential component and a common mode
component. The common mode input impedance is a
function of the clock frequency and the control bit LPF1.
The differential input impedance is a function of the clock
frequency and the control bits LPF1, GAIN1 and GAIN0.
Table 4 shows the typical input impedances for a clock
frequency of 90MHz. These input impedances are all proportional to 1/fCLK, so if the clock frequency were reduced
5
6602 F09
Figure 9. Distortion vs Common Mode Input Voltage (5V)
by half to 45MHz, the impedances would be doubled. The
typical part to part variation in dynamic input impedance
for a given clock frequency is –20% to +35%.
Table 4. Differential, Common Mode Input Impedances,
fCLK = 90MHz
GAIN1
GAIN0
LPF1
Differential Input
Impedance (kΩ)
Common Mode Input
Impedance (kΩ)
0
0
0
16
20
0
0
1
6
6.7
0
1
0
8
20
0
1
1
2.8
6.7
1
0
0
2.6
20
1
0
1
1.8
6.7
1
1
0
2.4
20
1
1
1
1.3
6.7
Output Common Mode and Differential Voltage Range
The output voltage is a fully differential signal with a
common mode level equal to the voltage at VOCM. Any of
the filter outputs may be used as single-ended outputs,
although this will degrade the performance. The output
voltage range is typically 0.5V to V+A – 0.5V (V+A = 2.7V
to 3.6V).
The common mode output voltage can be adjusted by
overdriving the voltage present on VOCM. To maximize
the undistorted peak-to-peak signal swing of the filter,
the VOCM voltage should be set to V+A /2. Note that the
6602fa
19
LTC6602
APPLICATIONS INFORMATION
VSUPPLY
–20
DISTORTION (dBc)
–30
0.1μF
–40
LTC6602
V+IN
V+A
–50
V+D
–60
HD3
–70
–80
HD2
–90
0.5
TA = 25°C
fIN = 100kHz
VIN = 1.5VP-P
RBIAS = 54.9k
45kHz-300kHz BPF
GAIN = 0dB
VIN+
+
–
VIN–
1.0
1.5
2.0
2.5
COMMON MODE OUTPUT VOLTAGE (V)
+
–
+INA
+OUTA
VOUT+
–INA
–OUTA
VOUT–
VOCM
1μF
GND
DC COUPLED INPUT
VIN (COMMON MODE) = (VIN+ + VIN–)/2
VOUT (COMMON MODE) = (VOUT+ + VOUT–)/2 = VSUPPLY/2
6602 F10
6602 F11
Figure 10. Distortion vs Common Mode Output Voltage
VSUPPLY
VSUPPLY
0.1μF
RPULL-UP
RPULL-UP
+
–
VIN–
LTC6602
0.1μF
V+IN
1.87k
V+D
+
–
0.1μF
1μF
VSUPPLY
VSUPPLY
V+A
0.1μF
VIN+
Figure 11. DC Coupled Inputs
1.87k
V+A
V+D
0.1μF
+INA
–OUTA
–INA
–OUTB
VOCM
VIN+
1.87k
VIN–
+
–
LTC6602
V+IN
+
–
0.1μF
1.87k
1μF
+INA
–OUTA
–INA
–OUTB
VOCM
GND
GND
6602 F12b
6602 F12a
AC COUPLED INPUT
VIN (COMMON MODE) = VSUPPLY/2
AC COUPLED INPUT =
RCM • VSUPPLY
= COMMON MODE AT +INA AND –INA
2 • RCM + 1.87k
(b) Variable Lowpass Cutoff Frequency
(a) Fixed Lowpass Cutoff Frequency
Figure 12. AC Coupled Inputs
output common mode voltages of the two channels are
not independent as they are both set by the VOCM pin.
Figure 10 illustrates the distortion versus output common
mode voltage for a 1.5VP-P differential input voltage and a
common mode input voltage that is equal to mid-supply.
Interfacing to the LTC6602
The input and output common mode voltages of the
LTC6602 are independent. The input common mode voltage is set by the signal source if DC coupled, as shown in
Figure 11. If the inputs are AC coupled, the input common mode voltage will pulled to ground by an equivalent
resistance of RCM, shown in Table 4. This does not affect
the filter’s performance as long as the input amplitude
is less than 0.5VP-P. At low filter gain settings, a larger
input voltage swing may be desired. Figure 12 shows two
circuits with AC coupled inputs. In a fixed lowpass cutoff
frequency, connecting resistors between each input and
V+IN will pull the input common mode voltage up, increasing the input signal swing (Figure 12a). The resistance,
RPULL-UP, necessary to set the input common mode
voltage, VICM, to any desired level can be calculated by
V
RPULLUP = RCM SUPPLY 1
VICM
where
RCM = 20k • 90MHz/fCLK for LPFI = 0
RCM = 6.7k • 90MHz/fCLK for LPFI = 1
For example, if the lowpass cutoff frequency is set to
300kHz, 20k resistors connected between each input
and V+IN will set the input common mode voltage to
mid-supply.
6602fa
20
LTC6602
APPLICATIONS INFORMATION
3.3V
3.3V
LTC6602
MASTER
0.1μF
V+IN
RBIAS
V+A
V+IN
+INA
RBIAS
–INA
RBIAS
V+D
+OUTA
VIN1
–
RBIAS
V+A
V+D
+
LTC6602
SLAVE
0.1μF
–OUTA
+
+
VOUT1
VIN2
–
–
+INA
+OUTA
+
VOUT2
–INA
CLKCNTL
CLKCNTL
CLKIO
CLKIO
GND
GND
–OUTA
–
6602 F13
Figure 13. Two Filters in a Master/Slave Configuration
If the lowpass cutoff frequency varies then the Figure 12b
circuit must be used.
The output common mode voltage is equal to the voltage
of the VOCM pin. The VOCM pin is biased to one half of the
supply voltage by an internal resistive divider (see Block
Diagram). To alter the common mode output voltage, VOCM
can be driven with an external voltage source or resistor
network. If external resistors are used, it is important to
note that the internal 1.6k resistors can vary ±30% (their
ratio varies only ±1%). The filter outputs can also be AC
coupled.
The LTC6602 can be interfaced to an A/D converter by pulling CLKCNTL (Pin 5) to V+D. This configures CLKIO (Pin 15)
as a clock output, which can be used to drive the clock
input of the A/D converter. This allows the A/D converter
to be synchronized with the filter sampling clock, avoiding
“beat frequencies” and simplifying the board layout. Any
routing attached to the CLKIO pin should be as short as
possible, in order to minimize ringing.
Similarly, two LTC6602s can be connected in a master/
slave configuration as shown in Figure 13. This results
in four matched filter channels, all synchronized to the
same clock. The master has its CLKCNTL pin pulled to
V+D, configuring its CLKIO pin as an output, while the
slave has its CLKCNTL pin pulled to ground, configuring
its CLKIO pin as an input.
Output Drive
The filter outputs can drive 1k and/or 50pF loads connected
to AC ground with a 0.5V to 2.5V signal (corresponding
to a 4VP-P differential signal). For differential loads (loads
connected between +OUTA and –OUTA or +OUTB and
–OUTB) the outputs can produce a 4VP-P signal across 2k
and/or 25pF. For smaller signal amplitudes, the outputs can
drive correspondingly heavier loads. For larger capacitive
loads, an external 50Ω series resistor is recommended
for each output.
6602fa
21
LTC6602
APPLICATIONS INFORMATION
Mute Function
The LTC6602 features a mute function which is asserted
by pulling MUTE (Pin 20) to ground. This breaks the signal
path that leads from the input pins to the filter networks,
attenuating the input signal by at least 20dB. The mute
function can be used to protect the filter inputs from large
transients. The filter clock continues to run when the filter
is muted, allowing for a fast recovery time when MUTE
is de-asserted. Typically, the recovery time is less than
5μs, as shown in Figure 14. When the mute function is
asserted, the differential input impedance becomes very
high, but the common mode input impedance to ground
remains the same. This keeps the input common mode
voltage stable when muted, even when the inputs are
AC coupled. Connecting GAIN0(D0) to MUTE allows for
serial control of the mute function. MUTE has an internal
pull-up to V+D.
MUTE (2V/DIV)
VOUT (1V/DIV)
4μs/DIV
6602 F14
Figure 14. Mute Function Recovery Time
Clock Feedthrough
Clock feedthrough is defined as the RMS value of the clock
frequency and its harmonics that are present at the filter’s
output. The clock feedthrough is measured with +INA and
–INA (or +INB, –INB) tied to VOCM and depends on the PC
board layout and the power supply decoupling. The clock
feedthrough can be reduced with a simple RC post filter.
DC Offset
The output DC offset of the LTC6602 is less than ±15mV.
To obtain optimum DC offset performance, appropriate
PC board layout techniques should be used. The filter
IC should be soldered to the PC board. The power supplies should be well decoupled including 0.1μF ceramic
capacitors from V+D (Pin 16) and V+A (Pin 2) to ground.
A ground plane should be used. Noisy signals should be
isolated from the filter input pins.
The output DC offset typically changes less than ±2mV when
the clock frequency varies from 24.705MHz to 90MHz. The
offset is measured by connecting the inputs to VOCM and
measuring the differential voltage at the filter’s output.
Aliasing
Aliasing is an inherent phenomenon of sampled data filters.
Significant aliasing only occurs when the frequency of the
input signal approaches the sampling frequency or multiples of the sampling frequency. The ratio of the LTC6602
input sampling frequency to the clock frequency, fCLK, is
determined by the state of control bit LPF1. If LPF1 is set
to ‘0’, the input sampling frequency is equal to fCLK/3. If
LPF1 is set to ‘1’, the input sampling frequency is equal to
fCLK. Input signals with frequencies near the input sampling
frequency will be aliased to the passband of the filter and
appear at the output unattenuated.
A simple LC anti-aliasing filter is recommended at the filter
inputs to attenuate frequencies near the input sampling
frequency that will be aliased to the passband. For example,
if the clock frequency is set to 90MHz and the lowpass
cutoff frequency of the filter is set to it’s maximum (LPF1
= ‘1’), the lowest frequency that would be aliased to the
passband would be fCLK – fCUTOFF, i.e. 90MHz – 900kHz =
89.1MHz. In order to attenuate this frequency by 40dB, an
LC filter with a cutoff frequency of 8.91MHz or lower would
be required at the filter inputs. The capacitor connected
between the LTC6602 filter inputs should be at least 150pF
to provide sufficient charge to the input sampler. If there
is no anti-aliasing filter, the LTC6602 filter inputs should
be driven by a low impedance source (<100Ω).
Wideband Noise
The wideband noise of the filter is the RMS value of the
device’s output noise spectral density. The wideband noise
voltage is used to determine the operating signal-to-noise
ratio at a given distortion level. The wideband noise is
nearly independent of the value of the clock frequency
and excludes the clock feedthrough. Most of the wideband
noise is concentrated in the filter passband and cannot be
removed with post filtering.
6602fa
22
LTC6602
APPLICATIONS INFORMATION
120
fCLK (MHz)
SUPPLY CURRENT (mA)
100
HPF1 = 0 HPF1 = 0
HPF0 = 0 HPF0 = 1
10
LPF1 = 1
LPF1 = 0
LPF0 = 1
10k
100k
FILTER CUTOFF FREQUENCY (Hz)
60
40
20
HPF1 = 1 LPF1 = 0
HPF0 = 0 LPF0 = 0
1k
TA = 25°C
VS = 3V
100 CLKCNTL PIN FLOATING
HPF1 = 0
HPF0 = 1
80 GAIN = 0dB
0
10k
1M
LPF1 = 0
LPF0 = 0
LPF1 = 0
LPF0 = 1
LPF1 = 1
100k
LOWPASS CUTOFF FREQUENCY (Hz)
6602 F15
1M
6602 F16
Figure 15. fCLK vs Filter Cutoff Frequencies
Figure 16. Supply Current vs Lowpass Cutoff Frequency
Table 5. Total Input Referred Integrated Noise Voltage (Passband Gain = 30dB)
LPF1
LPF0
HPF1
HPF0
Noise Voltage
0
0
0
0
–90dBm
0
1
0
1
–89dBm
1
X
1
0
–82dBm
Power Supply Current
The power supply current depends on the state of the
lowpass cutoff frequency controls (LPF1, LPF0) and the
value of RBIAS. When the LTC6602 is programmed for the
lowest lowpass cutoff frequency (LPF1 = LPF0 = ‘0’), the
supply current is reduced by about 35% relative to the
supply current for the higher bandwidth settings. Power
supply current vs. cutoff frequency for various bandwidth
settings is shown in the “Typical Performance Characteristics” section. The LTC6602 can be programmed through the
serial interface to enter into a low power shutdown mode
as described in the Serial Interface section. The power
supply current during shutdown is less than 235μA.
Supply Current versus Noise Tradeoff
The passband of the LTC6602 is determined by the master
clock frequency (which is set by RBIAS when the internal
oscillator is used), HPF1, HPF0, LPF1 and LPF0. The
LTC6602 is optimized for use with RBIAS having a value
between 200k and 54.9k to set the internal oscillation
frequency from 24.705MHz to 90MHz. Both lowpass
and highpass corner frequencies are proportional to the
clock frequency (internal or external). To extend the filter’s
operational frequency range, the master clock is divided
down before reaching the filter. LPF1 and LPF0 set the division ratio of the lowpass clock while HPF1 and HPF0 set
the division ratio of the highpass clock. Figure 15 shows
the possible cutoff frequencies versus fCLK, HPF1, HPF0,
LPF1 and LPF0. Overlapping frequency ranges allow more
than one possible choice of bandwidth settings for some
cutoff frequencies. Figure 16 shows supply current as a
function of the lowpass cutoff frequency, LPF1 and LPF0.
Note that the higher bandwidth setting always gives the
minimum supply current for a given cutoff frequency. The
total integrated noise voltage for a passband gain of 30dB
is shown in Table 5. Note that the noise is higher for the
higher bandwidth settings. This creates a tradeoff between
supply current and noise. For a given cutoff frequency,
using the highest possible bandwidth setting gives the
minimum supply current at the expense of higher noise.
6602fa
23
LTC6602
APPLICATIONS INFORMATION
The LTC6602, an Adaptable Baseband Filter for an
RFID Reader
A radio-frequency identification (RFID) system is an auto-id
technology that identifies any object that contains a coded
tag. An RFID system consists of a reader (or interrogator)
and a tag. An RFID system capable of identifying multiple
tags at a maximum operating distance operates in the
UHF frequency range. A UHF reader transmits information to a tag by modulating an RF signal in the 860MHz
to 960MHz frequency range. Typically a tag is passive,
meaning that it receives all of its operating energy from a
reader that transmits a continuous wave (CW) RF signal
to power a tag. A tag responds by modulating the reflection coefficient of its antenna, thereby backscattering an
information signal to the reader. Reliable detection of a
tag signal requires communication protocols that define
the physical and operating interaction between readers
and tags. The latest UHF RFID protocol, the Electronic
Product Code™ (EPC) global class-1 generation 2 standard
(C1G2), have been accepted worldwide and is also known
as ISO 18000-6C. The C1G2 standard defines a reader to
tag and a tag to reader communication using a flexible
set of signal modulation, data encoding, data rates and
command procedures. C1G2 specifies reader and tag data
symbols using pulse-interval encoding. Tag signal detection requires measuring the time interval between signal
transitions (a data “1” symbol has a longer interval than
a data “0” symbol). The reader initiates a tag inventory by
sending a signal that instructs a tag to set its backscatter
data rate and encoding. C1G2 certified RFID readers can
operate in an RF environment where many readers are in
close proximity. The three operating modes of C1G2, single
interrogator, multiple interrogator and dense interrogator,
define the spectral limits of reader and tag signals for an
optimum balance of reliable multitag detection and high
data throughput (for more information on C1G2, consult
the references at the end of this design note). The advantages of C1G2 complex protocols can be realized by using
a reader whose receiver contains a high linearity direct
conversion I and Q demodulator, a low noise amplifier, a
dual baseband filter with variable gain and bandwidth and
a dual analog to digital converter (ADC).
Certified C1G2 UHF RFID readers can adapt to a great
variety of operating conditions. To achieve operating
flexibility a reader’s baseband circuits must include an
adaptable bandwidth filter. Figure 17 shows an LTC6602
based filter circuit that uses SPI control to vary the filter’s
bandwidth to adjust for the C1G2 complex set of data rates,
encoding and modulation. The filter’s clock frequency is
set by the SPI control of 8-bit LTC2630 DAC (digital to
analog converter). The DAC voltage through a resistive
divider sets the current into the LTC6602 RBIAS pin. The
resistive divider sets the clock frequency range for a DAC
voltage range 0V to 3V. For the resistor values in Figure 17
(191k and 61.9k) the clock frequency range is 40MHz to
100MHz (234.4kHz per bit). The lowpass and highpass
division ratio is set by the SPI control of the LTC6602. The
cutoff range for the highpass filter is 6.7kHz to 100kHz and
for the lowpass filter is 66.7kHz to 1MHz. The optimum
filter bandwidth setting can be adjusted by a software
algorithm and is a function of the reader’s data clock, data
rate, encoding and modulation. The filter bandwidth must
be sufficiently narrow to maximize the dynamic range to
the ADC input and wide enough to preserve signal transitions and pulse width. If the filter setting is optimum then
a DSP algorithm can reliably detect tag data. Figure 18a
shows the filter’s time response to a typical tag symbol
sequence (a “short” pulse interval followed by a “long”
pulse interval). The lowpass cutoff frequency is set equal
to the reciprocal of the shortest interval (fCUTOFF = 1/10μs
= 100kHz). If the lowpass cutoff frequency is lower the
signal transition and time interval will be distorted beyond
recognition by any tag signal detection algorithm. The setting of the highpass cutoff frequency is more qualitative
than specific. The highpass cutoff frequency must be lower
than the reciprocal of the longest interval (for Figure 18
example, highpass fCUTOFF < 1/20μs < 50kHz) and as
high as possible to decrease the receiver’s low frequency
noise (baseband amplifier and down-converted phase and
amplitude noise). Figures 18a and 18b show the filter’s
total response (lowpass plus highpass filter). The filter’s
output is shown with 30kHz and a 10kHz highpass cutoff
frequency setting. Comparing the filter outputs with a
10kHz and a 30kHz highpass setting, the signal transitions
and time intervals of the 10kHz output are adequate for
6602fa
24
LTC6602
APPLICATIONS INFORMATION
detecting the symbol sequence (in an RFID environment,
noise will be superimposed on the output signal). In
general, increasing the lowpass fCUTOFF and/or decreasing
the highpass fCUTOFF “enhances” signal transitions and
intervals and increases filter output noise.
5V
3V
0.1μF
1
2
V+IN
V+A
24 +INA
SPI CONTROL OF DAC
SETS THE LTC6602
CLOCK FREQUENCY
40MHz TO 100MHz
1
2
3
CS
SDI
16
V+D
–OUTA 18
I CHANNEL INPUT 23 –INA
7 +INB
Q CHANNEL INPUT
8
VOUT
SCLK
0.1μF
GND
6
5
174k
0.1μF
4
0.1μF
68.1k
4
V+
3
20
21
3V
LTC2630
8-BIT DAC
TRANSMITTER
MUTE INPUT
DAC VOUT
RANGE 0V TO 2.5V
(USING THE LTC2630
INTERNAL REFERENCE)
22
14
25
+OUTA 19
I CHANNEL OUTPUT
–OUTB 12 Q CHANNEL OUTPUT
LTC6602
+OUTB 13
–INB
15
CLKIO
RBIAS
17
SER
VOCM
5
3V
CLKCNTL
MUTE
11
GAIN0(D0) HPFO(SDO)
10
HPFI(SDI)
GAIN1
SPI CONTROL OF LTC6602
9
SETS THE FILTER GAIN AND THE
LPFO(SCLK)
GND
LOWPASS AND HIGHPASS
6
LPF1(CS)
GND
DIVISION RATIO
ADC VCOM INPUT
CS1
SCK
SDI
CS2
6602 F17
Figure 17. An Adaptable RFID Baseband Filter with SPI Control
LOWPASS ONLY FILTER
100kHz LOWPASS + 30kHz HIGHPASS FILTER
100kHz LOWPASS + 10kHz HIGHPASS FILTER
0 10 20 30 40 50 60 70 80 90 100110120
(μs)
0 10 20 30 40 50 60 70 80 90 100110120
(μs)
100kHZ
LOWPASS
TYPICAL TAG
SYMBOL
SEQUENCE
0 10 20 30 40 50 60 70 80 90 100110120
(μs)
6602 F19c
6602 F19b
6602 F19a
(a)
(b)
(c)
Figure 18. Filter Transient Response to a Tag Symbol Sequence
6602fa
25
LTC6602
TYPICAL APPLICATIONS
Switching the RBIAS Resistor
3V
PARALLEL CONTROL
1
2
V+IN
V+A
16
24 +INA
–OUTA 18
+OUTA 19
23 –INA
7 +INB
8
4
R3
R2
0.1μF
R1
3
20
SOT-363
21
22
14
25
DIODES INC
DMN2004DMK
CLK1
CLK0
0
0
RBIAS1
0
1
RBIAS2
1
0
RBIAS3
1
1
RBIAS4
RBIAS1 > RBIAS2 OR RBIAS3
fCLK1
fCLK2
fCLK3
fCLK4
CLK1
0.1μF
V+D
–OUTB 12
LTC6602
+OUTB 13
–INB
RBIAS
CLKIO
VOCM
SER
MUTE
CLKCNTL
GAIN0(D0) HPF0(SDO)
HPF1(SDI)
GAIN1
GND
LPF0(SCLK)
GND
LPF1(CS)
15
17
5
3V
11
10
9
6
VOCM
MUTE
CLK0
GAIN1 GAIN0
LPF1
LPF0
HPF1
HPF0
DESIGN PROCEDURE
1. CHOOSE fCLK1, fCLK2 AND fCLK3
2. CALCULALTE RBIAS1, RBIAS2 AND RBIAS3
3. CALCULATE R2, R3 AND RBIAS4
RBIAS = 4941
fCLK
RBIAS1 IN k
fCLK IN MHz
R1 = RBIAS1
R2 = RBIAS1 • RBIAS2
RBIAS1 – RBIAS2
R3 = RBIAS1 • RBIAS3
RBIAS1 – RBIAS3
RBIAS4 =
R1 • R2 • R3
R1 • (R2 + R3) + R2 • R3
3V
SERIAL CONTROL
1
2
24 +INA
1
2
3
CS
SCLK
VOUT
GND
V+
SDI
LTC2630
8-BIT DAC
DAC VOUT
0V
2.5V
R1 =
8
R2
6
5
0.1μF
4
R1
4
0.1μF
3
20
21
22
3V
14
LTC6602 fCLK
fCLKHI
fCLKLO
1.056 • 1013
1.137 • fCLKHI + fCLKLO
R2 = 1.056 • 1013
fCLKHI – fCLKLO
25
0.1μF
V+D
–OUTA 18
+OUTA 19
23 –INA
7 +INB
DAC VOUT RANGE, 0V TO 2.5V
(USING LTC2630 INTERNAL REFERENCE)
16
V+A
V+IN
–OUTB 12
LTC6602
+OUTB 13
–INB
RBIAS
CLKIO
VOCM
SER
MUTE
CLKCNTL
GAIN0(D0) HPF0(SDO)
GAIN1
HPF1(SDI)
GND
LPF0(SCLK)
GND
LPF1(CS)
15
17
5
3V
11
10
9
6
VOCM
MUTE
CS1
SCLK
SDI
CS2
SDO
6602 TA02
6602fa
26
LTC6602
PACKAGE DESCRIPTION
UF Package
24-Lead Plastic QFN (4mm × 4mm)
(Reference LTC DWG # 05-08-1697)
0.70 p0.05
4.50 p 0.05
2.45 p 0.05
3.10 p 0.05 (4 SIDES)
PACKAGE OUTLINE
0.25 p0.05
0.50 BSC
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
4.00 p 0.10
(4 SIDES)
BOTTOM VIEW—EXPOSED PAD
R = 0.115
TYP
0.75 p 0.05
PIN 1 NOTCH
R = 0.20 TYP OR
0.35 s 45o CHAMFER
23 24
PIN 1
TOP MARK
(NOTE 6)
0.40 p 0.10
1
2
2.45 p 0.10
(4-SIDES)
(UF24) QFN 0105
0.200 REF
0.00 – 0.05
0.25 p 0.05
0.50 BSC
NOTE:
1. DRAWING PROPOSED TO BE MADE A JEDEC PACKAGE OUTLINE MO-220 VARIATION (WGGD-X)—TO BE APPROVED
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, IF PRESENT
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
6602fa
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.
27
LTC6602
TYPICAL APPLICATION
Direct Conversion Demodulator and Programmable Baseband Filter
RF IN
5V
4.7pF
3V
0.1μF
270nH*
0.1μF
10pF
270pF
4 3 2 1
GND GND RF GND 16
5
6
EN
VCC
7 V
CC
8
VCC
5V
1μF
0.1μF
15
LT5575
270nH*
1
V+IN
10pF
10pF
24 +INA
10pF
I INPUT 23 –INA
14
Q INPUT
10pF
1000pF
13
10pF
7 +INB
8 –INB
4
38.3k
270nH*
GND LO GND VCC
17
9 10 11 12
10pF
20
270pF
270nH*
0.1μF
10pF
21
22
1000pF
14
MUTE INPUT FROM TRANSMITTER
LO IN
3
4.7pF
25
2 16
V+A V+D
–OUTA 18
+OUTA 19 I OUTPUT
–OUTB 12
LTC6602
+OUTB 13
CLKIO
RBIAS
VOCM
SER
MUTE
CLKCNTL
GAIN0(D0) HPF0(SDO)
GAIN1
HPF1(SDI)
GND
LPF0(SCLK)
GND
LPF1(CS)
Q OUTPUT
15
17
CLOCK
INPUT
5
11
10
9
6
VOCM INPUT FROM ADC
CS SCLK SDI
SPI CONTROL INPUT
*COILCRAFT 0603HP-R27X
6602 TA03
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PART NUMBER
DESCRIPTION
COMMENTS
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800MHz to 2.7GHz Direct Conversoin I/Q Demodulator
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Balance Transformer
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Fully Differential Amplifier and Lowpass Filter
Cutoff Frequencies: 2.5MHz/5MHz/10MHz/20MHz
Programmable Gain, Adjustable Output CM Voltage,
Specified for 3V, 5V, ±5V
6602fa
28 Linear Technology Corporation
LT 0908 REV A • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
© LINEAR TECHNOLOGY CORPORATION 2008