Signal Processing Technologies, Inc.4755 Forge Road, Colorado Springs, Colorado 80907, USA
Phone: 719-528-2300 Fax: 719-528-2370 Web Site: http://www.spt.com e-mail: [email protected]
AN7610EVALUATION BOARD
APPLICATION NOTE
FEATURES
1 GSPS conversion rate On-board reconstruction DAC On-board reference circuit On-board adjustable reference Decimated digital data output Selectable decimation divide by 16/32/64 options
APPLICATIONS
Evaluation of SPT7610 6-bit ADCs Engineering system prototype aid Guide for design of SPT7610 interface circuitry Guide for design of SPT7610 PCB layout
SPECIAL REQUIREMENTS
The SPT7610 device requires adequate heat sinkingand air flow for optimum performance.
GENERAL DESCRIPTION
The EB7610 evaluation board is specifically designed fordevice characterization and demonstration of the perfor-mance of the SPT7610 A/D converter. The SPT7610 hasa guaranteed sample rate of 1 GSPS. At this high conver-sion speed, hand-crafted bread boards will not performeffectively, and a printed circuit board is a must. This appli-cation note should be used as a supplement to theSPT7610 data sheet to aid designers in achieving optimaldevice performance.
Figure 1 Block Diagram, Rev C
The EB7610 comes with the SPT7610SIQ in an 44-leadcerquad surface mount package directly soldered to theboard for optimum performance. The EB7610 is capableof operating at clock rates up to 1 GSPS. (Clock rateshigher than 1 GSPS are possible but not guaranteed.) Theblock diagram of the board is shown in figure 1. Note thatadequate air flow and a heat sink are necessary for opti-mum performance of the ADC.
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SPT7610 ADC OVERVIEW
The SPT7610 has a guaranteed minimum sample rate of1 GSPS. Only one 5.2 V power supply is required. Twoexternal references are applied across the internal refer-ence ladder, which has a resistance of 80 typical (60 minimum). The top reference is typically 0 V or con-nected to AGND (analog ground). The device has topforce and sense pins (VRFT and VRST) that are internallyconnected together. These voltage force and sense pinscan be used to minimize the voltage drop across theparasitic line resistance.
The bottom reference is typically 1 V. The device alsohas bottom force and sense pins (VRFB and VRSB) thatare internally connected together. These can also beused to minimize the voltage drop across the parasiticline resistance. Three additional reference taps (VR3 =0.25 V typ, VRM = 0.5 V typ, and VR1 = 0.75 V typ)are brought out. These taps can be used to control thelinearity error.
All logic levels are compatible with both 10K ECL or 100KECL. It is recommended that the clock input be driven dif-ferentially (CLK and NCLK) to improve noise immunityand reduce aperture jitter.
The digital outputs are split into two banks of 6-bit wordsand an overrange bit. Each bank is updated at 1/2 of theclock rate and are 180 out of phase from each other. Thedifferential data ready signals for each bank are providedto accurately latch each data bank into the register. Theoutput data is in a straight binary, inverted binary, twoscomplement or inverted twos complement format. (Refer
to the data sheet for details.) Figure 2 shows a timing dia-gram of the device and shows the input to output relation-ship, clock-to-output delay and output latency. TheSPT7610 has a built-in offset in the 2 clock divider (Dflip-flop) to assure that output bank A will come up firstafter power turn on.
The full-scale analog input bandwidth is 750 MHz(1.4 GHz for small signal bandwidth). The input capaci-tance is 8 pF (typical). Power dissipation is specified at2.85 W maximum at +25 C. Adequate air flow and aheat sink are necessary. The data sheet provides therequired information necessary for heat sink selectionand indicates the required air flow rates. Refer to theThermal Management section of the SPT7610 datasheet.
SPT7610 TEST MODE FUNCTION
The SPT7610 supports a special test mode function thatoverrides the SPT7610s internal data output latch stageand exercises the digital outputs in an alternating test pat-tern. This enables the user to test digital interface logicdownstream from the SPT7610 with a known set of digitaltest patterns.
Test mode pin 3 controls the SPT7610 mode of operationsuch that when it is low, the SPT7610 operates in normalmode. When test mode pin 3 is brought high, theSPT7610 will begin to output test pattern 1 (see table I) onthe next rising edge of the clock. (See figure 2.) It will out-put the test patterns alternating between test pattern 1and test pattern 2, as long as test mode pin 3 is held high.The minimum set-up time (tsu) can be as low as 0 nsec.
Figure 2 SPT7610 Timing Diagram
2
FIRSTRISING EDGE
POWER ON
8
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OUTPUTBANK B(DB0-6)
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DRB
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INVALID DATA
INVALID DATA INVALID DATA
7 9Bank A Test Pattern 1: - Even Bits = Hi - Odd Bits = Low
Bank B Test Pattern 1: - Even Bits = Hi - Odd Bits = Low
Bank A Test Pattern 2: - Even Bits = Low - Odd Bits = Hi
Bank B Test Pattern 2: - Even Bits = Low - Odd Bits = Hi
LOGIC LOW
SPT 3 1/12/01AN7610
Only the digital output stage is involved in the test modeoperation. All ADC stages before the digital output stagecontinue normal data conversion operation while testmode is active. When test mode pin 3 is brought back low,the SPT7610 will resume output of valid data on the nextrising edge of the clock. The valid data output will corre-spond to a two-clock-cycle pipeline delay as shown infigure 2.
Table I SPT7610 Test Mode Output Bit Patterns
D6 D5 D4 D3 D2 D1 D0Test Pattern 1 1 0 1 0 1 0 1Test Pattern 2 0 1 0 1 0 1 0
OPERATION AND CALIBRATION
POWER SUPPLIES AND GROUNDING
Inside the SPT7610 every circuit is biased from AGND toAVEE (analog), except the DGND pins. This includes theclock input circuitry. To minimize any ground loops and tooptimize performance, all interfacing circuits must bereferenced to the appropriate grounds.
The reference, analog input, and clock input drivers are tobe referenced to AGND. The DGND pins, digital outputloads, and all logic interfacing circuits are to be referencedto DGND. The block diagram on page 1 indicates clearlywhere the AGND and DGND are split. The AGND andDGND are tied to each other through a ferrite bead asclose to the converter as possible. The EB7610 requiresthree power supplies as listed in the table below.
Table II EB7610 Power Supply Requirements
Supply Voltage Range (V) Typical CurrentMin Typ Max (mA)
A5.2V 4.95 5.2 5.45 1000D2V 1.95 2.0 2.2 1200D4.5V 4.20 4.5 4.8 500
Figure 3 is the recommended power supply hookup for theevaluation board. SPT recommends that all power sup-plies be turned on and off at the same time via a powerstrip.
Table III Initial Setup of Board Jumpers/DipSwitches
OptionJumpers Status Switch Status
JB1 ..................... Short J6A, JA1............................ OpenJ2 ........................ Short J6B .................................... OpenJ3 ........................ Short J9A .................................... ShortJ4 ........................ Short A/B SEL ....................... LO or HIJ5A ..................... Short S0 ........................................... HIJ5B ..................... Short S1 ........................................... HI
SW5, SW6, SW7, SW8 ........ LO
PROCEDURE FOR VERIFYING BOARD OPERATION
To verify correct board operation: Connect power supplies and generators (leave off). Set jumpers and dip switches to proper configurations.
(See table III.) Turn on clock generator and set to 499.712 MHz and
1 VP-P. Turn on analog input generator and set to 3.965 MHz
and 1 VP-P. Turn on all power supplies and observe the 61 kHz
sinewave at the scope (64 points/period).Refer to Beat Frequency Technique section for moredetail.
REFERENCE CIRCUIT
Referring to the detailed schematic (see figure 8), D1 is a1.2 V Zener diode. R1 potentiometer is used as a refer-ence adjustable voltage to give 1.0 V 0.005 V at theVREF test point. This voltage is then buffered with U4A anddrives Q1, which is set up as an emitter follower. The emit-ter follower is necessary to sink up to 17 mA through thereference ladder (based on 1 V reference and 60 mini-mum ladder resistance). U4 (a low voltage rail-to-rail quadop-amp) is powered from GND to 5.2 V. The selection ofU4 prevents the reference from going positive duringpower on and keeps it to within the maximum rating(+0.5 V to AVEE).
The top reference is connected to AGND if JB1 is in-stalled. The top reference may be driven externallythrough the VRT banana jack (with respect to AG3 bananajack) by installing a jumper at JA1 instead of a jumper atJB1.
The SPT7610 has three reference ladder taps broughtout. These taps can be forced to their theoretical voltageto correct the bow in the transfer curve due to the injectionof the pre-amp input bias currents into the reference lad-der. VR3 is the 1/4 scale tap, VRM is the mid-scale tap, andVR1 is the 3/4 scale tap. For example, when VRTF = 0 V andVRBF = 1.0 V, VR3, VRM and VR1 should be forced to0.250 V, 0.500 V and 0.750 V respectively. Each tap isprovided with its test point. The potentiometers R2, R3,and R4 are provided for voltage adjustments to the taps.
Figure 3 Configuration of Power Supplies
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A 2.2 F decoupling capacitor in parallel with 0.1 F and100 pF surface-mount capacitors is recommended for allreference pins (VRTF, VR1, VRM, VR3, and VRBF). These ca-pacitors should be placed as close to the pin as possible.(The smallest value should be the closest.)
ANALOG INPUT
SPT was not able to locate an op-amp suitable to drive theSPT7610. It requires a bandwidth of at least 800 MHz andat least 40 dB of distortion. Given an input capacitanceof 8 pF, the required peak driving current is 2C=20 mA,for =400 MHz.
For AC input into the EB7610, connect the analog inputinto the VIN SMA. C51 is for coupling to the DUT. Applying0.5 V to the VOS banana jack (referenced to AGND) willoffset the input to meet the 0 to 1 V input range of theADC.
If DC input is required, inject the analog input through theVOS test point and place a ground cap on the VIN BNC.Figure 4 shows the DC-coupled input circuit with this con-figuration. Note: R34 is socketed.
Turn all power supplies on. Monitor the A2 test point with DVM and adjust the R5
potentiometer for 2 V 10 mV. Monitor the SB test point with DVM and adjust the R1
potentiometer for 1 V 5 mV. Measure/record VFT and VFB test points with DVM. Monitor the VR3 test point with DVM and adjust the R2
potentiometer for $-3%$-
+ VFT.
Monitor the VRM test point with DVM and adjust the R3
potentiometer for $-3%$-
+ VFT.
Monitor the VR1 test point with DVM and adjust the R4
potentiometer for $-3%$-#
+ VFT.
DIGITAL OUTPUT BUFFER/DECIMATION CIRCUIT
With the exception of U3 (10K logic family), all interfacinglogic chips (U8U16) are 100K logic family. The SPT7610requires an immediate digital output buffer. The digital out-puts are compatible with both 10K or 100K ECL logic fami-lies. All digital outputs are pulled down to digital 2 Vthrough 49.9 resistors. U8 is the Motorola MC100E167,2:1 MUX register. Each 6-bit digital output bank A or bankB is selected through U8 with an A/B switch. The selecteddata bank is updated at the rate of the data ready signaldivided by 4:
U11 is a programmable delay. U12 is the exclusive-or acting as a buffer or inverter
with the A/B switch (S2). U13 is the divide-by-4 counter.
Note that the data ready signals for bank A and for bank Bare opposite in phase. (See the SPT7610 timing diagram.)
U8 requires a minimum of 100 ps of setup time and 300 psof hold time. To meet these requirements, set delayswitches S0S3 to logic 0 (down) and set R7 to mid-range.R7 is a fine-tune delay control for U11, which gives arange of 0 to 80 ps from 0 to 4 V.
The second decimation is through U9 which is a hex D flipflop. U14 is the 2, 4, 8 clock generation chip. The de-sired divider value is selected through U15 (4:1 MUX) withS0 and S1 switches. (See table V.)
U16 is a clock distributor for U9, U5 (DAC) and the P1connector.
Table IV S0, S1 Setup
Overall Decimation (N)S1 S0 with Respect to CLK0 0 640 1 641 0 321 1 16
CLOCK CIRCUIT
The clock input driver uses a MC10EL16 (U3), which is asingle 10K ECL family logic differential line receiver. Its in-put is set up for AC coupling from a 1 VP-P (CLK IN) withR35 (49.9 terminating resistor) connected to VBB. TheCLK IN signal (1 VP-P 10%) must be present to pre-vent U3 from oscillating as the two inputs are bal-anced. It is important to note that the input commonmode range for U3 is 0.4 V maximum. U2 is a 2 Vregulator (from analog 5.2 V) used only for U3 outputload pulldown. Note that the clock circuits are biased fromthe analog supply. This is critical to maintain the optimumperformance.
CLK and NCLK test points are provided on board. Thesetest points physically resemble those in the schematic.The physical layout of the test points provides a shortground path to the scope probe ground.
EB7610 CALIBRATION
All measurements are with respect to AGND. Hook up power supplies as shown in figure 3. Refer to the initial setup section for jumper/switch
setup.
Figure 4 DC-Coupled Input Configuration
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SPT 5 1/12/01AN7610
DATA RECONSTRUCTION DAC
The decimated encoded data is reconstructed and thesignal can be viewed through the DAC OUT SMA. U24(SPT1018 or SPT1019) is a 275 MWPS, 8-bit video DAC.It is set up for a fixed gain with an output range from 0 to19 mA into a 51 load (R90 socket) or 0 to 960 mV. Alarger output voltage range can be attained by replacingR90 with a larger value as long as the output stays withinthe DAC output compliance voltage range of 1.2 V.
BOARD LAYOUT AND DESIGNCONSIDERATIONS
Both Microstrip and Strip Line PCB board technologieshave predictable characteristic impedances that can becontrolled to within 5%. Figure 5 shows the basic crosssection of each technology. For G-10 dielectric material,the propagation delay of the line is typically 148 ps/in forMicrostrip and 188 ps/in for Strip Line. Note that thepropagation delay is independent of line width.
The following is an outline of some of the key guidelinesused in the design of the EB7610 evaluation board:
1. Minimize the logic fan-out. Most of them have a fan-outof only one.
2. Avoid, if possible, any through-hole vias between thesending and receiving end of any high-speed lines. Apin-out pattern of the logic that requires criss-crossingof high-speed lines should be avoided if possible.
3. The loading resistor should be as close to the receivingend as possible on all high-speed lines.
4. All unterminated (open) lines must be less than 1/4 ofthe rise time of the signal divided by the transmissionline propagation delay to assure minimal reflection:
Open Line Length (inches) < 1/4 x (trise / tpd)
where: trise = rise time of the signal (ns)
tpd = 0.188 ns/in (Strip Line characteristic)
tpd = 0.148 ns/in (Microstrip)
Table V shows the typical rise times versus the majorhigh-speed logic families with a fan-out of one.
5. Use a series damping resistor when an open line ex-ceeds the 1/4 x (trise / tpd) maximum.
6. Keep the analog circuitry separate from the digital cir-cuitry, including isolation of grounds. AGND and DGNDmust be tied together through a ferrite bead or an in-ductor as close to the ADC as possible.
7. Ensure adequate decoupling of the supplies.
8. Surface mount resistors and capacitors work better forhigh-speed designs.
Table V Typical Rise Times versusMajor High-Speed Logic Families
ECL ECL SYNERGY SYNERGY SPECL10K 10KH 100E 100S SONY
trise (ns) 23.5 1.1 0.30.4 0.7 0.30.4
CHARACTERIZATION OF THE SPT7610USING THE EB7610 EVALUATION BOARD
This section has recommendations for how best to char-acterize the SPT7610 using the EB7610 evaluation board.The intent is to provide some basic principles and meth-ods of characterization that will enable the optimal perfor-mance of the SPT7610 to be viewed and characterized sothe proper design considerations can be made.
RECOMMENDED TEST SETUP
Figure 6 shows a simple block diagram of the recom-mended test setup.
Due to the complexity of the EB7610 design, both tech-niques were used to make routing easier. The line width is10 mil and has a 50 characteristic impedance. It is aneight-layer board stacked in the following manner:
Layer 1 = First controlled impedance signal layer(Microstrip)
Layer 2 = Ground layer*Layer 3 = Second controlled impedance signal layer
(Strip Line)Layer 4 = Ground layer*Layer 5 = Third controlled impedance signal layer (Strip
Line)Layer 6 = Ground layer*Layer 7 = Power layer (all supplies share the same layer)Layer 8 = Fourth controlled impedance signal layer
(Microstrip)*AGND and DGND share the same layer.
To minimize the logic skew, the line lengths in each stageare closely matched to within 0.05 inch, especially be-tween the A/D output and the second decimation circuit(U8).
Figure 5 Cross Sections of Microstrip andStrip Line PCB Board Technologies
Ground
Dielectric
Signal
Dielectric
Ground
Ground
Dielectric
Signal
Microstrip Strip Line
SPT 6 1/12/01AN7610
Figure 6 AC Test Setup Block Diagram
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SPT 7 1/12/01AN7610
The input frequency is calculated as follows:
IN = n C B
where:C = S/N Capture frequency
(Decimated frequency at P1)n = integerB = C / S Beat frequencyS = Number of sample points
EXAMPLECapturing a 4096 point FFT at the P1 connector with thefollowing constraints is desired:
S = 750 MHzIN = 50 MHz and 100 MHzMaximum update rate of the memory = 20 MHz
Solution:
a. For N = 64C = S/N = (750 x 106) / 64 = 11.71875 MHz < 20 MHz
b. The beat frequency:B = C/4096 = 2861.022949 Hz
c. Round off B to eliminate round off errors and toimprove source resolution:B = 2860, then work backwards:C = B x 4096 = 11.71456 MHzS = C x 64 = 749.73184 MHz
d. For n = 4, IN = 4 x C + B = 46.8611 MHzFor n = 9, IN = 9 x C B = 105.4339 MHz
e. ConclusionsS = 749.73184 MHzIN = 46.861101 MHz and 105.4339 MHzN = 64
For convenience, table VII shows example setup param-eters for 4096-point beat frequency tests.
Method 1 Characterization Through the DACOutputWith the setup in table VII, the DAC output signal would bea sinewave at B and consists of 4096 points/period(1/B). The DAC reconstruction signal is used to ensureproper setup of the evaluation board and can be useddirectly for characterization purposes. The performance ofthe device can be viewed from DAC Out signal with aspectrum analyzer.
The analog input offset and gain can be adjusted by moni-toring the DAC Out with a scope.
The DAC Out signal can be used to verify the delay of theclock to the first stage decimation so that the setup andhold times are met. Refer to the Digital Output Buffer/
Decimation Circuit section and set the delay line switchesaccordingly until no glitches or spikes appear in the DACoutput signal.
Method 2 Noise Characterization Through DACOutputNoise is inherent to an ADC as a DC noise or noise floor. Itcould be identified simply by inputting a DC input andmeasuring the number of code counts. The simpler andmore accurate way to measure this noise is to input a slowramp and measure the code transition noise through theDAC output. The slope of the ramp input suggests at least10 capture data per LSB or slope (LSB x C)/10.
With certain types of ADCs, this transition code noisechanges with the input frequency. The beat frequencytechnique offers a tool for characterizing the code transi-tion noise at higher input frequencies. Table VII is thesetup for S = 4096 points per beat period. The code transi-tion noise could be viewed through DAC Out with a scopeby reducing S to a much smaller number of points perperiod (32 or 64 points).
Method 3 Characterization Through the P1ConnectorFrom table VII, 4096 points FFT can be performed fromthe data output at P1 (37-pin D shell connector). Refer tothe detailed schematic in figure 8 for the pin assignment.Note that the reconstruction DAC output signal should beused before an FFT is taken to verify proper setup of theevaluation board (decimation setup and delay lineswitches) and analog input signal (offset and gain).
Table VII 4096-Point Beat Frequency Test Setup
N (Deci- BS (MHz) IN (MHz) mation) C (MHz) (Hz) n
500.039680 46.882535 32 15.62624 3815 3500.039680 109.387495 32 15.62624 3815 7500.039680 156.266215 32 15.62624 3815 10500.039680 203.144935 32 15.62624 3815 13500.039680 296.902375 32 15.62624 3815 19500.039680 406.286055 32 15.62624 3815 26749.731840 46.861100 64 11.71456 2860 4749.731840 105.4339 64 11.71456 2860 9749.731840 152.29214 64 11.71456 2860 13749.731840 199.15038 64 11.71456 2860 17749.731840 304.58142 64 11.71456 2860 26749.731840 398.2979 64 11.71456 2860 341001.39008 46.94398 64 15.64672 3820 31001.39008 93.88414 64 15.64672 3820 61001.39008 156.47102 64 15.64672 3820 101001.39008 203.41118 64 15.64672 3820 131001.39008 297.2915 64 15.64672 3820 191001.39008 406.81854 64 15.64672 3820 26
SPT 8 1/12/01AN7610
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C61
C62
C63
C64
C65
C66
C68
C69
C74
C75
C76
R1
R2
R3
R4
R10
R11
R12
R13
R14
R15
R18
R19
R20
R21
R22
R25
200
120
+
+
-A2
VOUT
VIN
Adj
LM33
7
2
10 F
-A5.
2
D2
D3
C8
C19
R5
R26
R27
R28 R
29
R30
R33
R34
1 k
R23
R35
R40
R41
-D4.
5
11X X
C67
R44
R45
R46 R
47R
48
R49
R50
R51
R52
R53
R11
5
R55
R66
R67
R68
R69
R70
R71
R72
R73
R74
R75
R76
R77
R81
R82
R83
R78
R79
R80
RN
4
RN5
RN
6
R87
D6B
6D
6A
10,1
6,22
DG
D6B
17
D6A
R42
R43
X X
2 28
MIN
V
LIN
V
MIN
V
LIN
V
3Te
stTe
st
CLK
/8
CC
LK
3
2
78
5
1
6
4
100EL
11
XX
R56
R57
16
(-1.
00 V
)
+1/4(
AD
491)
-D2
C77
P1
FB8
J6AJ6B
J5AJ5B
R1
-D2
100E
L34
MR
10
9
/EN
15
VB
B(2,
4,8)
C70
C73
R16 R17
-D2
R11
0
-D2
-D4.
59 16 15 14
S0 S1
VIH
-D2
100
R11
1
D4
C71
R63
-D2
-D4.
5
XX
C72
R62
R64
R65
100E
L57
/D1
D2
/D2
D3
/D3
/D0
D1
D0
Sel
0
Sel
1
U15
(4:1
MU
X)
CK
XX
R58
R59
R84
R95
R96
R94
R93
R92
R91
DG
1D
G2
FB
3
-2-D
4.5
.1F
10F
+.1
F
10 F
+
- D
2-
D4.
5D
GN
DD
GN
D
C3
C4
C29
C30
-D2
C80
C82
C84
C85
C78
R88
R89
R11
2
R85
R86
33
RN3
-D2
FAN
S P
OW
ER
+5V
MIN
I FA
N
+-
C31
C21
C202 3
IN /IN
7-9,
20
Q14
12,1
5,16
1
-D2
X XR9
R8
J9
Hea
tS
ink
C34
C81
C83
C79
C33
C35
C36
C12
100E
196
D3
D2
D1
D0
LEN
-D2
AB
VIH
28 /QX13
A/B
SE
L
2726
2524
01
23
(Del
ayLi
ne)
R6
R7
18
FT
UN
E
C5
R31
A
B
SPT 9 1/12/01AN7610
Figure 9 Timing Diagram, Rev C
U12(S2 = 0)
U13 ( 4)
0.65
U8
0.5
0.3
U14
U15
U16
U9
U10
0.65
1.1
0.63
0.8
0.25
N-3N-11
N-3
N-11-4xn N-3
N+1N+2
N-1 N
N+3
N+4
DRA(REF ONLY)
CLK(1GSPS)
U11 *(Tap = 0)
OUTPUT B N-3
OUTPUT A
DRB 1.4
N-1 N+1
NN-2N-4
N-5
N-6
0.9
1.4
N-11-4xn , where n = selected second decimations factor
*U11 output has a delay of 1.4 ns. See table VIII for additional delay times.
Table VIII U11 Output Delay Table
Typical TypicalAdditional Total
SW8 SW7 SW6 SW5 Delay (ps)* Delay (ps)*0 0 0 0 0 1,4000 0 0 1 18 1,4180 0 1 0 35 1,4350 0 1 1 53 1,4530 1 0 0 70 1,4700 1 0 1 88 1,4880 1 1 0 105 1,5050 1 1 1 123 1,523
Typical TypicalAdditional Total
SW8 SW7 SW6 SW5 Delay (ps)* Delay (ps)*1 0 0 0 140 1,5401 0 0 1 158 1,5581 0 1 0 175 1,5751 0 1 1 193 1,5931 1 0 0 210 1,6101 1 0 1 228 1,6281 1 1 0 245 1,6451 1 1 1 263 1,663
*FTune has a range from 0 to 80 ps, 0 to 4.0 V respectively.
SPT 10 1/12/01AN7610
Table IX EB7610 Bill of Materials
# Reference Part Number Description Qty Manufacturer1 C2-4 ECS-T1DC106R 10 F 20 V Tantalum Chip Cap 3 Panasonic/Any2 C5,12,50-59,61-73, 12062R103K9B20D .01F Chip Cap 30 Philips / Any
75-77,90,913 C6-11,19,27 ECS-T0JY106R 10 F 6.3V Tantalum Chip Cap 8 Panasonic/Any4 C1,13-18 ECS-T1CY225R 2.2 F Tantalum Chip Cap 7 Panasonic/Any5 C20-26,28-39,74,78-89 12062R104K9B20D .1 F Chip Cap 32 Philips / Any6 C40-48 1206CG101J9B200 100 pF Chip Cap 9 Philips / Any7 D1 ICL8069CCZQ-2 1.2 Volt Reference 1 Maxim8 D2-4 1N4001 Axial Diode 3 Any9 FB1-10 EXC-ELSA35V Ferrite Bead 10 Panasonic
10 J1 745189-1 37-Pin Vert Fem D-Sub Conn. 1 Amp11 J2-11 PZC36SAAN Jumper Pins (trim from 36-Pin) 1 Sullins12 J12-14 142-0701-201 RF (SMA) Connector 3 Johnson13 J15-23 108-0740-001 Banana Jack 9 Johnson14 Q1 2N2907A PNP Transistor 1 Fairchild15 R1-4,7 3266W-1-102 1K Potentiometer 5 Bourns16 R5 3266W-1-200 200 Ohm Potentiometer 1 Bourns17 R6 MFR-25FBF 2000 200 Ohm Axial Resistor [socketed] 1 Yageo / Any18 R8,9,16-18-22,24,31,35, ERJ-8ENF49R9 50 Ohm Chip Resistor 67 Panasonic/Any
40-45,47-59,62-89,90-96,110,112
19 R10-15,23 ERJ-8ENF1001 1K Ohm Chip Resistor 7 Panasonic/Any20 R25 ERJ-8ENF2671 2.67K Chip Resistor 1 Panasonic/Any21 R26,46,111 ERJ-8ENF1210 121 Ohm Chip Resistor 3 Panasonic/Any22 R27-30 ERJ-8ENF22R1 22 Ohm Chip Resistor 4 Panasonic/Any23 R33,34 MFR-25FBF 51R1 51 Ohm Axial Resistor [socketed] 1 Yageo / Any24 RN3,5 EXB-H8E470J 47 Ohm SMD Res Network 2 Panasonic25 RN4,6 766-143-R33 33 Ohm SMD Res Array 2 CTS26 S0-2,SW5-8 EG1218 Slide Switch 7 E-Switch
SW9-11 > Do Not Load27 TP1-20 40F6045 Solder Terminal 20 NEWARK28 U1 SPT7610 6-Bit, 1 GSPS ADC 1 SPT29 U2 LM337H Adj. Neg. Volt Regulator 1 National30 U3 MC10EL16D Diff. Receiver 1 ON Semi.31 U4 TLV2464CD R-R Op Amp 1 Tex. Instr.32 U5 SPT1019AIN 8-Bit DAC 1 SPT33 U8 MC100E167FN 6-Bit, 2:1 Mux-Register 1 ON Semi.34 U9 MC100E151FN 6-Bit, D-Register 1 ON Semi.35 U10 SY100S350JC Hex D-Latch 1 Synergy36 U11 MC100E196FN Prog. Delay Chip 1 ON Semi.37 U12 MC100EL07D XOR / XNOR Gate 1 ON Semi.38 U13 MC100EL33D Divider / 4 1 ON Semi.39 U14 MC100EL34D Clock Gen. Chip 1 ON Semi.40 U15 MC100EL57D 4:1 Diff. Mux 1 ON Semi.41 U16 MC10EL11D 1:2 Diff. Fanout Buffer 1 ON Semi.42 N/A ED5044-ND Pin Receptacles [for socketed parts] 6 DIGI-KEY43 N/A 929955-06 Shunt for Jumper 10 DIGI-KEY (3M)44 N/A 2206K-ND1 1.5" Spacer 4 DIGI-KEY45 N/A H143-ND1 4-40 Pan-head Screw 4 DIGI-KEY46 EB7610 Rev C Evaluation Board 1 SAS
1Mount in four corners as bottom side legs.
SPT 11 1/12/01AN7610
Figure 10 Top Layer Component
SPT 12 1/12/01AN7610
Figure 11 Layers 2, 4, 6 Ground
SPT 13 1/12/01AN7610
Figure 12 Layer 3 Inner Signal Layer 1
SPT 14 1/12/01AN7610
Figure 13 Layer 5 Inner Signal Layer 2
SPT 15 1/12/01AN7610
Figure 14 Layer 7 Power
SPT 16 1/12/01AN7610
Figure 15 Bottom Layer Solder