AD6645 14-Bit, 80/105 MSPS A/D Converter Data Sheet (REV. B)

AD6645

14-Bit, 80/105 MSPS

A/D Converter

Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties that
may result from its use. No license is granted by implication or otherwise
under any patent or patent rights of Analog Devices. Trademarks and
registered trademarks are the property of their respective companies.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700

www.analog.com

Fax: 781/326-8703

REV. B

FEATURES
SNR = 75 dB, f

15 MHz up to 105 MSPS

SNR = 72 dB, f

200 MHz up to 105 MSPS

SFDR = 89 dBc, f

70 MHz up to 105 MSPS

100 dB Multitone SFDR
IF Sampling to 200 MHz
Sampling Jitter 0.1 ps
1.5 W Power Dissipation
Differential Analog Inputs
Pin Compatible to AD6644
Twos Complement Digital Output Format
3.3 V CMOS Compatible
DataReady for Output Latching

APPLICATIONS
Multichannel, Multimode Receivers
Base Station Infrastructure
AMPS, IS-136, CDMA, GSM, WCDMA
Single Channel Digital Receivers
Antenna Array Processing
Communications Instrumentation
Radar, Infrared Imaging
Instrumentation

PRODUCT DESCRIPTION

The AD6645 is a high speed, high performance, monolithic 14-bit
analog-to-digital converter. All necessary functions, including
track-and-hold (T/H) and reference, are included on the chip to
provide a complete conversion solution. The AD6645 provides
CMOS compatible digital outputs. It is the fourth generation in a
wideband ADC family, preceded by the AD9042 (12-bit, 41 MSPS),

the AD6640 (12-bit, 65 MSPS, IF sampling), and the AD6644
(14-bit, 40 MSPS/65 MSPS).

Designed for multichannel, multimode receivers, the AD6645
is part of Analog Devices' SoftCell

transceiver chipset. The

AD6645 maintains 100 dB multitone, spurious-free dynamic
range (SFDR) through the second Nyquist band. This break-
through performance eases the burden placed on multimode
digital receivers (software radios) that are typically limited by the
ADC. Noise performance is exceptional; typical signal-to-noise
ratio is 74.5 dB through the first Nyquist band.

The AD6645 is built on Analog Devices' high speed complemen-
tary bipolar process (XFCB) and uses an innovative, multipass
circuit architecture. Units are available in a thermally enhanced
52-lead PowerQuad 4

(LQFP_PQ4) specified from 40

°C to

+85

°C at 80 MSPS and 10°C to +85°C at 105 MSPS.

PRODUCT HIGHLIGHTS

1. IF Sampling

The AD6645 maintains outstanding ac performance up to
input frequencies of 200 MHz, suitable for multicarrier 3G
wideband cellular IF sampling receivers.

2. Pin Compatibility

The ADC has the same footprint and pin layout as the
AD6644, 14-Bit 40 MSPS/65 MSPS ADC.

3. SFDR Performance and Oversampling

Multitone SFDR performance of 100 dBc can reduce the
requirements of high end RF components and allows the
use of receive signal processors such as the AD6620 or
AD6624/AD6624A.

FUNCTIONAL BLOCK DIAGRAM

TH2

TH4

ADC3

TH5

TH3

TH1

DAC1

ADC2

DAC2

ADC1

AIN

VREF

ENCODE

GND

DMID

OVR

DRY

D13

MSB

D12

D11

D10

LSB

INTERNAL

TIMING

DIGITAL ERROR CORRECTION LOGIC

AD6645

2.4V

REV. B

AD6645SPECIFICATIONS

DC SPECIFICATIONS

Test

AD6645ASQ-80

AD6645ASQ-105

Parameter

Temp

Level

Min

Typ

Max

Min

Typ

Max

Unit

RESOLUTION

Bits

ACCURACY

No Missing Codes

Full

Guaranteed

Offset Error

Full

+1.2

+10

+1.2

+10

Gain Error

Full

+10

% FS

Differential Nonlinearity (DNL)

Full

1.0

±0.25

+1.5

1.0

±0.5

+1.5

LSB

Integral Nonlinearity (INL)

Full

±0.5

±1.5

LSB

TEMPERATURE DRIFT

Offset Error

Full

1.5

ppm/

°C

Gain Error

Full

ppm/

°C

POWER SUPPLY REJECTION (PSRR)

°C

±1.0

mV/V

REFERENCE OUT (VREF)

Full

2.4

ANALOG INPUTS (AIN,

AIN)

Differential Input Voltage Range

Full

2.2

V p-p

Differential Input Resistance

Full

Differential Input Capacitance

°C

1.5

POWER SUPPLY

Supply Voltages

Full

4.75

5.0

5.25

4.75

5.0

5.25

Full

3.0

3.3

3.6

3.0

3.3

3.6

Supply Current

I AV

(AV

= 5.0 V)

Full

275

320

275

320

I DV

(DV

= 3.3 V)

Full

Rise Time

Full

250

POWER CONSUMPTION

Full

1.5

1.75

1.5

1.75

NOTES

VREF is provided for setting the common-mode offset of a differential amplifier such as the AD8138 when a dc-coupled analog input is required. VREF should be
buffered if used to drive additional circuit functions.

Specified for dc supplies with linear rise time characteristics.

Specifications subject to change without notice

DIGITAL SPECIFICATIONS

Test

AD6645ASQ-80

AD6645ASQ-105

Parameter (Conditions)

Temp

Level Min

Typ

Max

Min

Typ

Max

Unit

ENCODE INPUTS (ENC,

ENC)

Differential Input Voltage

Full

0.4

V p-p

Differential Input Resistance

°C

Differential Input Capacitance

°C

2.5

LOGIC OUTPUTS (D13D0, DRY, OVR

)

Logic Compatibility

CMOS

Logic 1 Voltage (DV

= 3.3 V)

Full

2.85

Logic 0 Voltage (DV

= 3.3 V)

Full

0.2

0.5

0.2

0.5

Output Coding

Twos Complement

DMID

Full

NOTES

All ac specifications tested by driving ENCODE and

ENCODE differentially.

The functionality of the Overrange bit is specified for a temperature range of 25

°C to 85°C only.

Digital output logic levels: DV

= 3.3 V, C

LOAD

= 10 pF. Capacitive loads >10 pF will degrade performance.

Specifications subject to change without notice.

(AV

= 5 V, DV

= 3.3 V; T

MIN

and T

MAX

at rated speed grade, unless otherwise noted.)

(AV

= 5 V, DV

= 3.3 V; T

MIN

and T

MAX

at rated speed grade, unless otherwise noted.)

REV. B

AD6645

AC SPECIFICATIONS

Test

AD6645ASQ-80

AD6645ASQ-105

Parameter (Conditions)

Temp

Level

Min

Typ

Max

Min

Typ

Max

Unit

SNR

Analog Input

15.5 MHz

°C

75.0

@ 1 dBFS

30.5 MHz

Full

72.5

74.5

37.7 MHz

°C

72.5

74.5

70.0 MHz

Full

72.0

73.5

72.0

73.5

150.0 MHz

°C

73.0

200.0 MHz

°C

72.0

SINAD

Analog Input

15.5 MHz

°C

75.0

@ 1 dBFS

30.5 MHz

Full

72.5

74.5

37.7 MHz

°C

72.5

74.5

70.0 MHz

Full

73.0

150.0 MHz

°C

68.5

67.5

200.0 MHz

°C

62.5

WORST HARMONIC (Second or Third)

Analog Input

15.5 MHz

°C

93.0

93.1

dBc

@ 1 dBFS

30.5 MHz

Full

85.0

93.0

dBc

37.7 MHz

°C

85.0

93.0

dBc

70.0 MHz

Full

89.0

87.0

dBc

150.0 MHz

°C

70.0

dBc

200.0 MHz

°C

63.5

dBc

WORST HARMONIC (Fourth or Higher)

Analog Input

15.5 MHz

°C

96.0

dBc

@ 1 dBFS

30.5 MHz

Full

85.0

95.0

dBc

37.7 MHz

°C

86.0

95.0

dBc

70.0 MHz

Full

90.0

dBc

150.0 MHz

°C

90.0

dBc

200.0 MHz

°C

88.0

dBc

TWO TONE SFDR @30.5 MHz

2, 3

°C

100

98.0

dBFS

55.0 MHz

2, 4

°C

100

98.0

dBFS

70.0 MHz

2, 5

°C

98.0

dBFS

TWO TONE IMD REJECTION

3, 4

F1, F2 @ 7 dBFS

°C

dBc

ANALOG INPUT BANDWIDTH

°C

270

MHz

NOTES

All ac specifications tested by driving ENCODE and

ENCODE differentially.

Analog input signal power swept from 10 dBFS to 100 dBFS.

F1 = 30.5 MHz, F2 = 31.5 MHz.

F1 = 55.25 MHz, F2 = 56.25 MHz.

F1 = 69.1 MHz, F2 = 71.1 MHz.

Specifications subject to change without notice.

SWITCHING SPECIFICATIONS

Test

AD6645ASQ-80

AD6645ASQ-105

Parameter (Conditions)

Temp

Level

Min

Typ

Max

Min

Typ

Max

Unit

Maximum Conversion Rate

Full

105

MSPS

Minimum Conversion Rate

Full

MSPS

ENCODE Pulsewidth High (t

ENCH

)

Full

5.625

4.286

ENCODE Pulsewidth Low (t

ENCL

)

Full

5.625

4.286

*Several timing parameters are a function of t

ENCL

and t

ENCH

Specifications subject to change without notice.

(AV

= 5 V, DV

= 3.3 V; ENCODE,

ENCODE, T

MIN

and T

MAX

at rated speed grade, unless

otherwise noted.)

(AV

= 5 V, DV

= 3.3 V; ENCODE,

ENCODE, T

MIN

and T

MAX

at rated speed grade, unless otherwise noted.)

REV. B

AD6645

(AV

= 5 V, DV

= 3.3 V; ENCODE,

ENCODE, T

MIN

and T

MAX

at rated speed grade,

LOAD

= 10 pF, unless otherwise noted.)

SWITCHING SPECIFICATIONS

(continued)

Test

AD6645ASQ-80

AD6645ASQ-105

Parameter (Conditions)

Name Temp Level

Min

Typ

Max

Min

Typ

Max

Unit

ENCODE Input Parameters

Encode Period

ENC

Full

12.5

9.5

Encode Pulsewidth High

ENCH

Full

6.25

4.75

Encode Pulsewidth Low

ENCL

Full

6.25

4.75

ENCODE/DataReady

Encode Rising to DataReady Falling

Full

1.0

2.0

3.1

1.0

2.0

3.1

Encode Rising to DataReady Rising

E_DR

Full

ENCH

+ t

ENCH

+ t

(50% Duty Cycle)

Full

7.3

8.3

9.4

5.7

6.75

7.9

ENCODE/DATA (D13:0), OVR

ENC to DATA Falling Low

E_FL

Full

2.4

4.7

7.0

2.4

4.7

7.0

ENC to DATA Rising Low

E_RL

Full

1.4

3.0

4.7

1.4

3.0

4.7

ENCODE to DATA Delay (Hold Time) t

H_E

Full

1.4

3.0

4.7

1.4

3.0

4.7

ENCODE to DATA Delay (Setup Time) t

S_E

Full

ENC

E_FL(max)

ENC

E_FL(max)

ENC

E_FL(typ)

ENC

E_FL(typ)

ENC

E_FL(min)

ENC

E_FL(min)

(50% Duty Cycle)

Full

5.3

7.6

10.0

2.3

4.8

7.0

DataReady (DRY

)/DATA, OVR

DataReady to DATA Delay (Hold Time) t

H_DR

Full

Note 4

(50% Duty Cycle)

6.6

7.2

7.9

5.1

5.7

6.4

DataReady to DATA Delay (Setup Time) t

S_DR

Full

Note 4

(50% Duty Cycle)

2.1

3.6

5.1

0.6

2.1

3.5

APERTURE DELAY

°C V

500

APERTURE UNCERTAINTY (Jitter)

°C

0.1

ps rms

NOTES

Several timing parameters are a function of t

ENC

and t

ENCH

ENCODE TO DATA Delay (Hold Time) is the absolute minimum propagation delay through the analog-to-digital converter, t

E_RL

= t

H_E

DRY is an inverted and delayed version of the encode clock. Any change in the duty cycle of the clock will correspondingly change the duty cycle of DRY.

DataReady to DATA Delay (t

H_DR

and t

S_DR

) is calculated relative to rated speed grade and is dependent on t

ENC

and duty cycle.

Specifications subject to change without notice.

S_DR

AIN

N+1

N+2

N+3

N+4

ENC

ENCH

ENCL

E_FL

E_RL

E_DR

S_E

H_E

H_DR

N+1

N+2

N+3

N+4

N1

N2

N3

ENC,

ENC

D[13:0], OVR

DRY

Figure 1. Timing Diagram

REV. B

AD6645

THERMAL CHARACTERISTICS

52-Lead Power Quad 4 LQFP_PQ4

= 23

°C/W Soldered Slug, No Airflow

= 17

°C/W Soldered Slug, 200 LFPM Airflow

= 30

°C/W Unsoldered Slug, No Airflow

= 24

°C/W Unsoldered Slug, 200 LFPM Airflow

= 2

°C/W Bottom of Package (Heatslug)

Typical 4-Layer JEDEC Board Horizontal Orientation

ORDERING GUIDE

Model

Temperature Range

Package Description

Package Option

AD6645ASQ-80

°C to +85°C (Ambient) 52-Lead PowerQuad 4 (LQFP_PQ4) SQ-52

AD6645ASQ-105

°C to +85°C (Ambient) 52-Lead PowerQuad 4 (LQFP_PQ4) SQ-52

AD6645-80/PCB

Evaluation Board

AD6645-105/PCB

Evaluation Board

CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate
on the human body and test equipment and can discharge without detection. Although the AD6645
features proprietary ESD protection circuitry, permanent damage may occur on devices subjected to
high energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid
performance degradation or loss of functionality.

ABSOLUTE MAXIMUM RATINGS

Parameter

Min

Max

Unit

ELECTRICAL

Voltage

Analog Input Voltage

Analog Input Current

Digital Input Voltage

Digital Output Current

ENVIRONMENTAL

-80 Operating Temperature Range (Ambient)

+85

°C

-105 Operating Temperature Range (Ambient)

+85

°C

Maximum Junction Temperature

150

°C

Lead Temperature (Soldering, 10 sec)

300

°C

Storage Temperature Range (Ambient)

+150

°C

* Absolute maximum ratings are limiting values to be applied individually and beyond which the serviceability

of the circuit may be impaired. Functional operability is not necessarily implied. Exposure to absolute
maximum rating conditions for an extended period of time may affect device reliability.

EXPLANATION OF TEST LEVELS
Test Level

100% production tested.

II.

100% production tested at 25

°C and guaranteed by design

and characterization at temperature extremes.

III. Sample tested only.
IV. Parameter is guaranteed by design and characterization

testing.

Parameter is a typical value only.

REV. B

AD6645

PIN CONFIGURATION

52 51 50 49 48

43 42 41 40

47 46 45 44

14 15 16 17 18 19 20 21 22 23 24 25 26

PIN 1
IDENTIFIER

TOP VIEW

(Not to Scale)

AD6645

GND

DRY

D13 (MSB)

D12

D11

D10

GND

VREF

GND

ENC
ENC

GND

AIN
AIN

GND

D0 (LSB)

DMID

GND

OVR

DNC

GND

DNC = DO NOT CONNECT

PIN FUNCTION DESCRIPTIONS

Pin No.

Mnemonic

Function

1, 33, 43

3.3 V Power Supply (Digital) Output Stage Only.

2, 4, 7, 10, 13,

GND

Ground.

15, 17, 19, 21,
23, 25, 27, 29,
34, 42

VREF

2.4 V Reference. Bypass to ground with a 0.1

µF microwave chip capacitor.

ENC

Encode Input. Conversion initiated on rising edge.

ENC

Complement of ENC, Differential Input.

8, 9, 14, 16, 18,

5 V Analog Power Supply.

22, 26, 28, 30

AIN

Analog Input.

AIN

Complement of AIN, Differential Analog Input.

Internal Voltage Reference. Bypass to ground with a 0.1

µF chip capacitor.

Internal Voltage Reference. Bypass to ground with a 0.1

µF chip capacitor.

DNC

Do not connect this pin.

OVR

Overrange Bit. A logic level high indicates analog input exceeds

±FS.

DMID

Output Data Voltage Midpoint. Approximately equal to (DV

)/2.

D0 (LSB)

Digital Output Bit (Least Significant Bit); Twos Complement.

3741, 4450

D1D5, D6D12

Digital Output Bits in Twos Complement.

D13 (MSB)

Digital Output Bit (Most Significant Bit); Twos Complement.

DRY

DataReady Output.

*The functionality of the overrange bit is specified for a temperature range of 25

°C to 85°C only.

REV. B

AD6645

DEFINITIONS OF SPECIFICATIONS
Analog Bandwidth

The analog input frequency at which the spectral power of the
fundamental frequency (as determined by the FFT analysis) is
reduced by 3 dB.

Aperture Delay

The delay between the 50% point of the rising edge of the
ENCODE command and the instant at which the analog input
is sampled.

Aperture Uncertainty (Jitter)

The sample-to-sample variation in aperture delay.

Differential Analog Input Resistance, Differential Analog
Input Capacitance, and Differential Analog Input Impedance

The real and complex impedances measured at each analog
input port. The resistance is measured statically and the capaci-
tance and differential input impedances are measured with a
network analyzer.

Differential Analog Input Voltage Range

The peak-to-peak differential voltage that must be applied to
the converter to generate a full-scale response. Peak differential
voltage is computed by observing the voltage on a single pin and
subtracting the voltage from the other pin, which is 180 degrees
out of phase. Peak-to-peak differential is computed by rotating
the inputs' phase 180 degrees and taking the peak measurement
again. Then the difference is computed between both peak
measurements.

Differential Nonlinearity

The deviation of any code width from an ideal 1 LSB step.

Encode Pulsewidth/Duty Cycle

Pulsewidth high is the minimum amount of time that the
ENCODE pulse should be left in Logic 1 state to achieve
rated performance; pulsewidth low is the minimum time
ENCODE pulse should be left in low state. See timing implica-
tions of changing t

ENCH

in text. At a given clock rate, these

specs define an acceptable ENCODE duty cycle.

Full-Scale Input Power

Expressed in dBm. Computed using the following equation:

Power

Full Scale

Full Scale rms

Input

0 001

log

| |

Harmonic Distortion, Second

The ratio of the rms signal amplitude to the rms value of the
second harmonic component, reported in dBc.

Harmonic Distortion, Third

The ratio of the rms signal amplitude to the rms value of the
third harmonic component, reported in dBc.

Integral Nonlinearity

The deviation of the transfer function from a reference line
measured in fractions of 1 LSB using a best straight line
determined by a least square curve fit.

Minimum Conversion Rate

The encode rate at which the SNR of the lowest analog
signal frequency drops by no more than 3 dB below the
guaranteed limit.

Maximum Conversion Rate

The encode rate at which parametric testing is performed.

Noise (For Any Range Within the ADC)

NOISE

SNR

Signal

dBm

dBc

dBFS

0 001

Where Z is the input impedance, FS is the full scale of the device
for the frequency in question; SNR is the value for the particular
input level; and Signal is the signal level within the ADC reported
in dB below full scale. This value includes both thermal and
quantization noise.

Output Propagation Delay

The delay between a differential crossing of ENCODE and
ENCODE and the time when all output data bits are within
valid logic levels.

Power Supply Rejection Ratio

The ratio of a change in input offset voltage to a change in power
supply voltage.

Power Supply Rise Time
The time from when the dc supply is initiated until the supply
output reaches the minimum specified operating voltage for the
ADC. The dc level is measured at the supply pin(s) of the ADC.

Signal-to-Noise-and-Distortion (SINAD)

The ratio of the rms signal amplitude (set 1 dB below full scale)
to the rms value of the sum of all other spectral components,
including harmonics but excluding dc.

Signal-to-Noise Ratio (without Harmonics)

The ratio of the rms signal amplitude (set at 1 dB below full
scale) to the rms value of the sum of all other spectral compo-
nents, excluding the first five harmonics and dc.

Spurious-Free Dynamic Range (SFDR)

The ratio of the rms signal amplitude to the rms value of the peak
spurious spectral component. The peak spurious component
may or may not be a harmonic. May be reported in dBc (i.e.,
degrades as signal level is lowered) or dBFS (always related
back to converter full scale).

Two Tone Intermodulation Distortion Rejection

The ratio of the rms value of either input tone to the rms value of
the worst third order intermodulation product; reported in dBc.

Two Tone SFDR

The ratio of the rms value of either input tone to the rms value
of the peak spurious component. The peak spurious component
may or may not be an IMD product, may be reported in dBc
(i.e., degrades as signal level is lowered) or in dBFS (always
related back to converter full scale).

Worst Other Spur

The ratio of the rms signal amplitude to the rms value of the
worst spurious component (excluding the second and third
harmonics) reported in dBc.

REV. B

AD6645

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

ENCODE = 80MSPS
AIN = 2.2MHz @ 1dBFS
SNR = 75.0dB
SFDR = 93.0dBc

dBFS

TPC 1. Single Tone @ 2.2 MHz

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

dBFS

ENCODE = 80MSPS
AIN = 15.5MHz @ 1dBFS
SNR = 75.0dB
SFDR = 93.0dBc

TPC 2. Single Tone @ 15.5 MHz

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

ENCODE = 80MSPS
AIN = 29.5MHz @ 1dBFS
SNR = 74.5dB
SFDR = 93.0dBc

dBFS

TPC 3. Single Tone @ 29.5 MHz

Typical Performance Characteristics

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

ENCODE = 80MSPS
AIN = 69.1MHz @ 1dBFS
SNR = 73.5dB
SFDR = 89.0dBc

dBFS

TPC 4. Single Tone @ 69.1 MHz

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

dBFS

ENCODE = 80MSPS
AIN = 150MHz @ 1dBFS
SNR = 73.0dB
SFDR = 70.0dBc

TPC 5. Single Tone @ 150 MHz

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

dBFS

ENCODE = 80MSPS
AIN = 200MHz @ 1dBFS
SNR = 72.0dB
SFDR = 64.0dBc

TPC 6. Single Tone @ 200 MHz

REV. B

AD6645

FREQUENCY MHz

SNR dB

ENCODE = 80MSPS @ AIN = 1dBFS
TEMP = 40 C, +25 C, +85 C

72.0

72.5

73.0

73.5

74.0

74.5

75.0

75.5

T = +25 C

T = +85 C

T = 40 C

TPC 7. Noise vs. Analog Frequency

ANALOG INPUT FREQUENCY MHz

WORST-CASE HARMONIC dBc

ENCODE = 80MSPS @ AIN = 1dBFS
TEMP = 40 C, +25 C, +85 C

T = +25 C

T = 40 C, +85 C

TPC 8. Harmonics vs. Analog Frequency

ANALOG FREQUENCY MHz

SNR dB

100

ENCODE = 80MSPS @ AIN = 1dBFS
TEMP = 25 C

120

140

160

180

200

TPC 9. Noise vs. Analog Frequency (IF)

ANALOG FREQUENCY MHz

HARMONICS dBc

100

ENCODE = 80MSPS @ AIN = 1dBFS
TEMP = 25 C

120

140

160

180

200

100

WORST OTHER SPUR

HARMONICS (2ND, 3RD)

TPC 10. Harmonics vs. Analog Frequency (IF)

ANALOG INPUT POWER LEVEL dBFS

WORST-CASE SPURIOUS dBFS AND dBc

0
90

100

110

80

70

60

50

40

30

20

ENCODE = 80MSPS
AIN = 30.5MHz

dBc

SFDR = 90dB
REFERENCE LINE

120

dBFS

10

TPC 11. Single Tone SFDR @ 30.5 MHz

ANALOG INPUT POWER LEVEL dBFS

WORST CASE SPURIOUS dBFS AND dBc

0
90

100

110

80

70

60

50

40

30

20

ENCODE = 80MSPS
AIN = 69.1MHz

dBc

SFDR = 90dB
REFERENCE LINE

120

dBFS

10

TPC 12. Single Tone SFDR @ 69.1 MHz

REV. B

AD6645

ENCODE = 80MSPS
AIN = 30.5MHz,
31.5MHz (7dBFS)
NO DITHER

FREQUENCY MHz

130

3
5

120

110

100

90

80

70

60

50

40

30

20

10

dBFS

2F1 F2

2F2 + F1

2F1 + F2

F2 F1

2F2 F1

F1 + F2

TPC 13. Two Tones @ 30.5 MHz and 31.5 MHz

INPUT POWER LEVEL F1 = F2 dBFS

WORST-CASE SPURIOUS dBFS AND dBc

0
77

100

110

67

57

47

37

27

17

ENCODE = 80MSPS
F1 = 30.5MHz
F2 = 31.5MHz

dBc

dBFS

SFDR = 90dB
REFERENCE LINE

TPC 14. Two Tone SFDR @ 30.5 MHz and 31.5 MHz

ENCODE FREQUENCY MHz

SNR, WORST-CASE SPURIOUS dB

AND dBc

105

WORST SPUR @ AIN = 2.2MHz

SNR @ AIN = 2.2MHz

100

TPC 15. SNR, Worst Spurious vs. Encode @ 2.2 MHz

2F2 F1

ENCODE = 80MSPS
AIN = 55.25MHz,
56.25MHz (7dBFS)
NO DITHER

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

dBFS

F1 + F2

2F1 F2

2F2 + F1

2F1 + F2

F2 F1

TPC 16. Two Tone SFDR @ 55.25 MHz and 56.25 MHz

77

67

57

47

37

27

17

INPUT POWER LEVEL F1 = F2 dBFS

WORST-CASE SPURIOUS dBFS AND dBc

100

110

ENCODE = 80MSPS
F1 = 55.25MHz
F2 = 56.25MHz

dBc

dBFS

SFDR = 90dB
REFERENCE LINE

TPC 17. Two Tone SFDR @ 55.25 MHz and 56.25 MHz

ENCODE FREQUENCY MHz

SNR, WORST-CASE SPURIOUS dB

AND dBc

105

WORST SPUR @ AIN = 69.1MHz

SNR @ AIN = 69.1MHz

TPC 18. SNR, Worst Spurious vs. Encode @ 69.1 MHz

REV. B

AD6645

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

dBFS

ENCODE = 80.0MSPS
AIN = 30.5MHz @ 29.5 dBFS
NO DITHER

TPC 19. 1 M FFT without Dither

ANALOG INPUT LEVEL

100

110

dBFS

ENCODE = 80.0MSPS
AIN = 30.5MHz
NO DITHER

SFDR = 90 dB
REFERENCE LINE

WORST-CASE SPURIOUS dBc

TPC 20. SFDR without Dither

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

dBFS

ENCODE = 76.8MSPS
AIN = 69.1MHz @
1dBFS
SNR = 73.5dB
SFDR = 89.0dBc

TPC 21. Single Tone 69.1 MHz: Encode = 76.8 MSPS

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

dBFS

ENCODE = 80.0MSPS
AIN = 30.5MHz @ 29.5dBFS
WITH DITHER @ 19.2 dBm

TPC 22. 1 M FFT with Dither

ANALOG INPUT LEVEL

90

100

110

80

70

60

50

40

30

20

10

dBFS

ENCODE = 80.0MSPS
AIN = 30.5MHz
WITH DITHER @ 19.2 dBm

SFDR = 90 dB
REFERENCE LINE

SFDR = 100 dB
REFERENCE LINE

WORST-CASE SPURIOUS dBc

TPC 23. SFDR with Dither

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

dBFS

ENCODE = 76.8MSPS
AIN = WCDMA @ 69.1MHz

TPC 24. WCDMA Tone 69.1 MHz: Encode = 76.8 MSPS

REV. B

AD6645

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

dBFS

ENCODE = 76.8MSPS
AIN = 2WCDMA @ 59.6MHz

TPC 25. 2 WCDMA Carriers @ A

= 59.6 MHz:

Encode = 76.8 MSPS

FREQUENCY MHz

2.5

5.0

7.5 10.0 12.5 15.0 17.5 20.0 22.5 25.0 27.5 30.0

130

120

110

100

90

80

70

60

50

40

30

20

10

ENCODE = 61.44MSPS
AIN = 4WCDMA @ 46.08MHz

dBFS

TPC 26. 4 WCDMA Carriers @ A

= 46.08 MHz:

Encode = 61.44 MSPS

FREQUENCY MHz

130

120

110

100

90

80

70

60

50

40

30

20

10

ENCODE = 76.8MSPS
AIN = WCDMA @ 140MHz

dBFS

TPC 27. WCDMA Tone 140 MHz: Encode = 76.8 MSPS

130

120

110

100

90

80

70

60

50

40

30

20

10

ENCODE = 61.44MSPS
AIN = WCDMA @ 190MHz

dBFS

FREQUENCY MHz

2.5

5.0

7.5 10.0 12.5 15.0 17.5 20.0 22.5 25.0 27.5 30.0

TPC 28. WCDMA Tone 190 MHz: Encode = 61.44 MSPS

REV. B

AD6645

THEORY OF OPERATION

The AD6645 analog-to-digital converter (ADC) employs a three-
stage subrange architecture. This design approach achieves the
required accuracy and speed while maintaining low power and
small die size.

As shown in the functional block diagram, the AD6645 has
complementary analog input pins, AIN and

AIN. Each analog

input is centered at 2.4 V and should swing

±0.55 V around this

reference (see Figure 2). Since AIN and

AIN are 180 degrees out

of phase, the differential analog input signal is 2.2 V p-p.

Both analog inputs are buffered prior to the first track-and-hold,
TH1. The high state of the ENCODE pulse places TH1 in hold
mode. The held value of TH1 is applied to the input of a 5-bit
coarse ADC1. The digital output of ADC1 drives a 5-bit digital-
to-analog converter, DAC1. DAC1 requires 14 bits of precision,
which is achieved through laser trimming. The output of DAC1
is subtracted from the delayed analog signal at the input of TH3
to generate a first residue signal. TH2 provides an analog pipe-
line delay to compensate for the digital delay of ADC1.

The first residue signal is applied to a second conversion stage
consisting of a 5-bit ADC2, 5-bit DAC2, and pipeline TH4.
The second DAC requires 10 bits of precision, which is met
by the process with no trim. The input to TH5 is a second resi-
due signal generated by subtracting the quantized output of
DAC2 from the first residue signal held by TH4. TH5 drives
a final 6-bit ADC3.

The digital outputs from ADC1, ADC2, and ADC3 are added
together and corrected in the digital error correction logic to
generate the final output data. The result is a 14-bit parallel
digital CMOS compatible word, coded as twos complement.

APPLYING THE AD6645
Encoding the AD6645

The AD6645 encode signal must be a high quality, extremely
low phase noise source to prevent degradation of performance.
Maintaining 14-bit accuracy places a premium on encode clock
phase noise. SNR performance can easily degrade by 3 dB4 dB
with 70 MHz analog input signals when using a high jitter clock
source. See AN-501, Aperture Uncertainty and ADC System Per-
formance, for complete details.

For optimum performance, the AD6645 must be clocked
differentially. The encode signal is usually ac-coupled into the
ENC and

ENC pins via a transformer or capacitors. These pins

are biased internally and require no additional bias.

Figure 8 shows one preferred method for clocking the AD6645.
The clock source (low jitter) is converted from single-ended to
differential using an RF transformer. The back-to-back Schottky
diodes across the transformer secondary limit clock excursions
into the AD6645 to approximately 0.8 V p-p differential. This
helps prevent the large voltage swings of the clock from feeding
through to other portions of the AD6645, and limits the noise
presented to the encode inputs.

ENCODE

0.1 F

T1-4T

HSMS2812

DIODES

AD6645

CLOCK

SOURCE

Figure 8. Crystal Clock Oscillator, Differential Encode

If a low jitter clock is available, another option is to ac-couple a
differential ECL/PECL signal to the encode input pins as shown
in Figure 9. The MC100EL16 (or same family) from ON-SEMI
offers excellent jitter performance.

ENCODE

AD6645

0.1 F

ECL/

PECL

Figure 9. Differential ECL for Encode

Driving the Analog Inputs

As with most new high speed, high dynamic range analog-to-
digital converters, the analog input to the AD6645 is differential.
Differential inputs improve on-chip performance as signals are
processed through attenuation and gain stages. Most of the
improvement is a result of differential analog stages having high
rejection of even-order harmonics. There are also benefits at the
PCB level. First, differential inputs have high common-mode
rejection of stray signals such as ground and power noise.
Second, they provide good rejection of common-mode signals
such as local oscillator feedthrough.

The AD6645 analog input voltage range is offset from ground
by 2.4 V. Each analog input connects through a 500

resistor

to the 2.4 V bias voltage and to the input of a differential buffer
(Figure 2). The resistor network on the input properly biases the
followers for maximum linearity and range. Therefore, the analog
source driving the AD6645 should be ac-coupled to the input
pins. Since the differential input impedance of the AD6645 is
1 k

, the analog input power requirement is only 2 dBm,

simplifying the driver amplifier in many cases. To take full advan-
tage of this high input impedance, a 20:1 transformer would be
required. This is a large ratio and could result in unsatisfactory
performance. In this case, a lower step-up ratio could be used.
The recommended method for driving the analog input of
the AD6645 is to use a 4:1 RF transformer. For example, if R

were set to 60.4

and R

were set to 25

, along with a 4:1

impedance ratio transformer, the input would match to a 50

source with a full-scale drive of 4.8 dBm. Series resistors (R

)

on the secondary side of the transformer should be used to
isolate the transformer from the A/D. This will limit the amount
of dynamic current from the A/D flowing back into the second-
ary of the transformer. The 50

impedance matching can also

be incorporated on the secondary side of the transformer as
shown in the evaluation board schematic (Figure 13).

AIN

ADT4-1WT

AD6645

ANALOG INPUT

SIGNAL

0.1 F

Figure 10. Transformer-Coupled Analog Input Circuit

In applications where dc-coupling is required, a differential
output op amp such as the AD8138 from Analog Devices can
be used to drive the AD6645 (Figure 11). The AD8138 op amp
provides single-ended-to-differential conversion, which reduces
overall system cost and minimizes layout requirements.

REV. B

AD6645

AIN

REF

AD8138

OCM

499

DIGITAL
OUTPUTS

Figure 11. DC-Coupled Analog Input Circuit

Power Supplies

Care should be taken when selecting a power source. The use of
linear dc supplies with rise times of <45 ms is highly recom-
mended. Switching supplies tend to have radiated components
that may be received by the AD6645. Each of the power supply
pins should be decoupled as closely to the package as possible
using 0.1

µF chip capacitors.

The AD6645 has separate digital and analog power supply pins.
The analog supplies are denoted AV

and the digital supply pins

are denoted DV

. Although analog and digital supplies may be

tied together, best performance is achieved when the supplies are
separate. This is because the fast digital output swings can couple
switching current back into the analog supplies. Note that AV

must be held within 5% of 5 V. The AD6645 is specified for
DV

= 3.3 V, as this is a common supply for digital ASICS.

Digital Outputs

Care must be taken when designing the data receivers for the
AD6645. It is recommended that the digital outputs drive a series
resistor followed by a gate such as the 74LCX574. To minimize
capacitive loading, there should only be one gate on each output
pin. An example of this is shown in the evaluation board schematic
of Figure 13. The digital outputs of the AD6645 have a constant
output slew rate of 1 V/ns. A typical CMOS gate combined with
a PCB trace will have a load of approximately 10 pF. Therefore,
as each bit switches 10 mA

(

)

of dynamic

current per bit will flow in or out of the device. A full-scale
transition can cause up to 140 mA (14 bits

× 10 mA/bit) of

current to flow through the output stages. The series resistors
should be placed as close to the AD6645 as possible to limit the
amount of current that can flow into the output stage. These
switching currents are confined between ground and the DV

pin.

Standard TTL gates should be avoided since they can appreciably
add to the dynamic switching currents of the AD6645. It should
be noted that extra capacitive loading will increase output timing
and invalidate timing specifications. Digital output timing is
guaranteed for output loads up to 10 pF.

Digital output states for given analog input levels are shown
in Table I.

Grounding

For optimum performance, it is highly recommended that a
common ground be utilized between the analog and digital
power planes. The primary concern with splitting grounds is
that dynamic currents may be forced to travel significant dis-
tances in the system before recombining back at the common
source ground. This can result in a large, undesirable ground
loop. The most common place for this to occur is on the digital
outputs of the ADC. Ground loops can contribute to digital noise
being coupled back onto the ADC front end. This can manifest
itself as either harmonic spurs, or very high order spurious products
that can cause excessive spikes on the noise floor. This noise
coupling is less likely to occur at lower clock speeds since the
digital noise has more time to settle between samples. In general,
splitting the analog and digital grounds can frequently contrib-
ute to undesirable EMI-RFI and should therefore be avoided.

Conversely, if not properly implemented, common grounding
can actually impose additional noise issues since the digital
ground currents are riding on top of the analog ground currents
in close proximity to the ADC input. To minimize the potential
for noise coupling further, it is highly recommended that mul-
tiple ground return traces/vias be placed such that the digital
output currents do not flow back towards the analog front end,
but are routed quickly away from the ADC. This does not re-
quire a split in the ground plane and can be accomplished by
simply placing substantial ground connections directly back to
the supply at a point between the analog front end and the digi-
tal outputs. The judicious use of ceramic chip capacitors
between the power supply and ground planes will also help
suppress digital noise. The layout should incorporate enough
bulk capacitance to supply the peak current requirements during
switching periods.

Layout Information

The schematic of the evaluation board (Figure 13) represents a
typical implementation of the AD6645. A multilayer board is
recommended to achieve best results. It is highly recommended
that high quality, ceramic chip capacitors be used to decouple
each supply pin to ground directly at the device. The pinout of
the AD6645 facilitates ease of use in the implementation of
high frequency, high resolution design practices. All of the digital
outputs are segregated to two sides of the chip, with the inputs on
the opposite side for isolation purposes.

Care should be taken when routing the digital output traces. To
prevent coupling through the digital outputs into the analog
portion of the AD6645, minimal capacitive loading should be
placed on these outputs. It is recommended that a fan-out of
only one gate should be used for all AD6645 digital outputs.

The layout of the encode circuit is equally critical. Any noise
received on this circuitry will result in corruption in the digitiza-
tion process and lower overall performance. The encode clock
must be isolated from the digital outputs and the analog inputs.

Table I. Twos Complement Output Coding

AIN

Output

Level

State

Code

REF

+ 0.55 V

REF

0.55 V

Positive FS

01 1111 1111 1111

REF

Midscale

00...0/11...1

REF

0.55 V

REF

+ 0.55 V

Negative FS

10 0000 0000 0000

REV. B

AD6645

Jitter Considerations

The signal-to-noise ratio (SNR) for an ADC can be predicted.
When normalized to ADC codes, the equation below accurately
predicts the SNR based on three terms. These are jitter, average
DNL error, and thermal noise. Each of these terms contributes
to the noise within the converter.

ANALOG

= analog input frequency

j rms

= rms jitter of the encode (rms sum of encode source and

internal encode circuitry)

= average DNL of the ADC (typically 0.41 LSB)

n = number of bits in the ADC
V

NOISE rms

= V rms thermal noise referred to the analog input of

the ADC (typically 0.9 LSB rms)

For a 14-bit analog-to-digital converter, like the AD6645, aper-
ture jitter can greatly affect the SNR performance as the analog
frequency is increased. The chart below shows a family of curves
that demonstrate the expected SNR performance of the AD6645
as jitter increases. The chart is derived from the equation below.

For a complete discussion of aperture jitter, see AN-501, Aper-
ture Uncertainty and ADC System Performance. The AN-501
Application Note can be found on

www.analog.com

JITTER ps

0.1

SNR dBFS

0.2

0.3

0.4

0.5

0.6

AIN = 110MHz

AIN = 150MHz

AIN = 190MHz

AIN = 30MHz

AIN = 70MHz

Figure 12. SNR vs. Jitter

SNR

ANALOG

j rms

(

)

1 76

log

OISE rms

REV. B

AD6645

Table II. AD6645ASQ/PCB Bill of Materials

Item
No.

Qty

Reference ID

Description

Manufacturer

6645EE01C

AD6644/AD6645 Evaluation Printed Circuit Board

PCSM, Inc. (6645EE01C)

C1, C2, C38

Capacitor, Tantalum SMT T491C, 10

µF; 16 V; 10%

Kemet (T491C106M016AS)

C3, C7C11, C16,

Capacitor, SMT 0508, 0.1

µF; 16 V; 10%

Presidio Components

C30, C32

(0508X7R104K16VP6)

C4, C22C26, C29,

Capacitor, SMT 0805, 0.1

µF; 25 V; 10%

Panasonic (ECJ-2VB1E104K)

(C33), (C34), C39

(C5, C6)

Capacitor, SMT 0805, 0.01

µF; 50 V; 10%

Panasonic (ECJ-2YB1H103K)

C12C14, C17C21,

Capacitor, SMT 0508, 0.01

µF; 16 V; 10%

Presidio Components

C40

(0508X7R103M2P3)

CR1

Diode, Schottky Barrier, Dual

Panasonic (MA716-TX)

E3, E4, E5

100" Straight Male Header (Single Row), 3 of 50 Pins

Samtec (TSW-1-50-08-G-S)

F1F4

EMI Suppression Ferrite Chip, SMT 0805

Steward (HZ0805E601R-00)

Connector, PCB Pin Strip; 5 Pins; 5 mm Pitch

Wieland (Z5.530.0525.0)

Connector, PCB Terminal; 5 Pins; 5 mm Pitch

Wieland (25.602.2553.0)

Terminal Strip, 50-Pin; Right Angle

Samtec (TSW-125-08-T-DRA)

(J3)

Connector, SMA; RF; Gold

Johnson Components, Inc.
(142-0701-201)

J4, J5

Connector, Coaxial RF Receptacle; 50

AMP (227699-2)

(R1)

Resistor, SMT 0402; 100

; 1/16 W; 1%

Panasonic (ERJ-2RKF1000X)

(R2)

Resistor, SMT 1206; 60.4

; 1/8 W; 1%

Panasonic (ERJ-8ENF60R4V)

(R3, R4, R5, R8)

Resistor, SMT 0805; 499

; 1/10 W; 1%

Panasonic (ERJ-6ENF4990V)

R6, R7

Resistor, SMT 0805; 25.5

; 1/10 W; 1%

Panasonic (ERJ-6ENF25R5V)

Resistor, SMT 0805; 348

; 1/10 W; 1%

Panasonic (ERJ-6ENF3480V)

R10

Resistor, SMT 0805; 619

; 1/10 W; 1%

Panasonic (ERJ-6ENF6190V)

(R11), (R13)

Resistor, SMT 0805; 66.5

; 1/10 W; 1%

Panasonic (ERJ-6ENF66R5V)

(R12), (R14)

Resistor, SMT 0805; 100

; 1/10 W; 1%

Panasonic (ERJ-6ENF1000V)

R15

Resistor, SMT 0402; 178

; 1/16 W; 1%

Panasonic (ERJ-2RKF1780X)

R35

Resistor, SMT 0805; 49.9

; 1/10 W; 1%

Panasonic (ERJ-6ENF49R9V)

RN1, RN3

Resistor Array, SMT 0402; 470

; 1/4 W; 5%

Panasonic (EXB2HV471JV)

RN2, RN4

Resistor Array, SMT 0402; 220

; 1/4 W; 5%

Panasonic (EXB2HV221JV)

RF Transformer, SMT KK81, 0.2350 MHz; 4:1

Ratio Mini-Circuits (T4-1-KK81)

RF Transformer, SMT CD542, 2775 MHz; 4:1

Ratio Mini-Circuits (ADT4-1WT)

I.C., QFP-52; 14-Bit, 80 MSPS

Analog Devices (AD6645ASQ)

Wideband Analog-to-Digital Converter

U2, U7

I.C., SOIC-20; Octal D-Type Flip-Flop

Fairchild (74LCX574WM)

(U3)

I.C., SOIC-8; Low Distortion Differential ADC Driver

Analog Devices (AD8138AR)

U4, U6

I.C., SMT SOT-23; TinyLogic UHS 2-Input OR Gate

Fairchild (NC7SZ32)

Clock Oscillator, Full Size MX045; 80 MHz

CTS Reeves (MXO45-80)

Connector, Miniature Spring Socket,

Amp (5-330808-3)

(U8)

I.C., SOIC-8; Differential Receiver

Motorola (MC100EL16)

See drawing

Circuit Board Support on Base

Richo (CBSB-14-01)

See drawing

0.100" Shorting Block

Jameco (152670)

NOTES

Reference designators in parentheses are not installed on standard units. (ac-coupled AIN and ENCODE.)

AC-coupled AIN is standard, R3, R4, R5, R8, and U3 are not installed.
If dc-coupled AIN is required, C30, T3, and R15 are not installed.
AC-coupled ENCODE is standard. C5, C6, C33, C34, R1, R11R14, and U8 are not installed.
If PECL ENCODE is required, CR1 and T2 are not installed.

R2 is installed for 50

impedance input matching on the primary of T3. R15 is not installed.

R15 is installed for 50

impedance input matching on the secondary of T3. R2 is not installed.

U5 clock oscillator is installed with pin sockets for removal if OPT_CLK input is used.

REV. B

AD6645

RN3

(SEE NOTE 4)

GND

CLOCK

OUT

VCC

GND

CLOCK

OUT_EN

VCC

RN1

(SEE NOTE 4)

R2 IS INSTALLED FOR INPUT MATCHING ON THE PRIMARY OF T3. R15 IS NOT INSTALLED.

R15 IS INSTALLED FOR INPUT MATCHING ON THE SECONDARY OF T3.

R2 IS NOT INSTALLED.

AC-COUPLED AIN IS STANDARD. R3, R4, R5, R8, AND U3 ARE NOT INSTALLED.

IF DC-COUPLED AIN IS REQUIRED, C30, R15, AND T3 ARE NOT INSTALLED.

AC-COUPLED ENCODE IS STANDARD. C5, C6, C33, C34, R1, R11R14 AND U8 ARE NOT INSTALLED.

IF PECL ENCODE IS REQUIRED, CR1, AND T3 ARE NOT INSTALLED.

IF AD6644 IS USED: VALUE FOR RN1RN4 IS 100 OHM.

IF AD6645 IS USED: VALUE FOR RN1RN3 IS 470 OHM, VALUE FOR RN2 AND RN4 IS 220 OHM.

NOTES

AD6644

/
AD6645

GND

VREF

GND

ENC

GND

AIN

GND

DMID

GND

OVR

DNC

GND

DRY

D13

D12

D11

D10

GND

DC-COUPLED AIN OPTION

GND

BUFLAT

FERRITE

VIN

3P3V

VIN

5V

C16

0.1

C17

0.01

C18

0.01

C19

0.01

C20

0.01

C21

0.01

C40

0.01

C39

0.1

C38

0.1

C10

0.1

C11

0.01

C12

0.01

C13

0.01

C14

0.01

C23

0.1

C24

0.1

C25

0.1

C26

0.1

+5VA

0.1

+5VA

PREF

GND

DR_OUT

C32

0.1

VREF

+5VA

RN4

(SEE NOTE 4)

R15

176.4

IMPEDANCE

RATIO

ADT4-1WT 4:1

C30

0.1

60.4

AIN

AD8138

R4 499

VREF

5V

+5VA

R5 499

499

C29

0.1

IMPEDANCE

RATIO

1:4

CR1

0.1

ENC

R35

49.9

R13

66.5

R14

100

C34

0.1

C33

0.1

R11

66.5

R12

100

+5VA

VBB

VCC

VEE

+5VA

0.01

100

0.01

PECL ENCODE OPTION

GND

FERRITE

+5VA

C22

0.1

VCC

OUT

GND

0.1

BUFLAT

DR_OUT

R10

619

348

K1115

66.66MHz (AD6644

)

80MHz (AD6645

)

OPT_CLK

BUFLAT

NC7SZ32

BNC

NC7SZ32

MC100EL16

74LCX574

FERRITE

+5VA

5V

SMA

OPT_LAT

OPTIONAL

HSMS2812

HEADER 50

74LCX574

B06

B07

B08

B09

B10

B11

B12

B13

B00

B01

B02

B03

B04

B05

OVR

RN2

(SEE NOTE 4)

Figure 13. Evaluation Board Schematic

REV. B

C0264707/03(B)

AD6645

OUTLINE DIMENSIONS

52-Lead Low Profile Quad Flat Package, Exposed Pad [LQFP-PQ4]

(SQ-52)

Dimensions shown in millimeters

0.65

BSC

0.38
0.32
0.22

12.00 SQ

10.00

BSC SQ

TOP VIEW

(PINS DOWN)

7.80 REF

1.60
MAX

VIEW A

SEATING

PLANE

0.75
0.60
0.45

EXPOSED

HEATSINK

(CENTERED)

2.35
2.20
2.05

(4 PLCS)

6.05
5.90
5.75

2.65
2.50
2.35

(4 PLCS)

BOTTOM VIEW

(PINS UP)

0.15
0.05

0.10

COPLANARITY

1.45
1.40
1.35

3.5

0.20
0.09

VIEW A

ROTATED 90 CCW

COMPLIANT TO JEDEC STANDARDS MS-026BCC-HD

Revision History

Location

Page

7/03--Data Sheet changed from REV. A to REV. B.

Changes to Title . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

Changes to FEATURES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

Changes to PRODUCT DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

Changes to SPECIFICATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2

Changes to ABSOLUTE MAXIMUM RATINGS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

Changes to ORDERING GUIDE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

Updated OUTLINE DIMENSIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

6/02--Data Sheet changed from REV. 0 to REV. A.

Change to DC SPECIFICATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

Document Outline

Ð­Ð»ÐµÐºÑ‚Ñ€Ð¾Ð½Ð½Ñ‹Ð¹ ÐºÐ¾Ð¼Ð¿Ð¾Ð½ÐµÐ½Ñ‚: AD6645ASQ-105

Document Outline

ÐÐ»ÐµÐºÑ‚Ñ€Ð¾Ð½Ð½Ñ‹Ð¹ ÐºÐ¾Ð¼Ð¿Ð¾Ð½ÐµÐ½Ñ‚: AD6645ASQ-105