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Edge629
1 GHz Timing Deskew and Quad Fanout Element
TEST AND MEASUREMENT PRODUCTS Description
The Edge629 is a monolithic timing delay and signal fanout solution manufactured in a high-performance bipolar process. In Automatic Test Equipment (ATE) applications, the Edge629 buffers, distributes, and aligns timing signals across multiple channels (typically found inside Memory Test Systems). It is also suitable for per pin deskew in Logic Testers. The Edge629 supports: * Minimum pulse width = 330 ps with Falling Edge Adjust disabled, 500 ps with Falling Edge Adjust enabled * Net usable delay span 4.0 ns * Falling Edge Adjust 250 ps * On Board DACs to generate 5 ps resolution With a maximum operating frequency of 1 GHz, the Edge629 is optimized for extremely high speed, high accuracy testers, particularly those aimed to test memory devices. The Edge629 solves several difficult problems associated with aligning multiple timing signals because it can: * delay very narrow pulses over a long timing span * adjust the falling edge independently from the overall propagation delay * maintain extreme timing accuracy for very narrow (sub-ns) pulses * maintain tight timing accuracy over changes in frequency, duty cycle, and pattern.
Featur es
* * * * * * * Fmax 1 GHz Independent Falling Edge Adjust Small Footprint (10 mm x 10 mm) Excellent Timing Accuracy Very Stable Timing Delays 5 ps Resolution ECL, CMOS Compatible Inputs
Functional Block Diagram
IN0 / IN0*
T-
T
Coarse
T
Fine
OUT0 / OUT0*
IN / IN*
IN1/ IN1*
T-
T
Coarse
T
Fine
OUT1 / OUT1*
IN2 / IN2*
T-
T
Coarse
T
Fine
OUT2 / OUT2*
Applications
* Memory Test Equipment - Data Fanout - Channel Deskew Logic Testers - Per Pin Deskew Clock / Signal Fanout
IN3 / IN3*
T-
T
Coarse
T
Fine
OUT3 / OUT3*
* *
SEL / SEL*
Revision 3 / August 1, 2005
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Edge629
TEST AND MEASUREMENT PRODUCTS PIN Description
Pin Name IN/IN* IN0, IN0* IN1/IN1* IN2/IN2* IN3/IN3* OUT0/OUT0* OUT1/OUT1* OUT2/OUT2* OUT3/OUT3* SEL/SEL* SDI CK CS UPDATE CATHODE, ANODE COMP0-3 DAC_FALL_(0-3) Pin # 9, 8 15, 16 11, 12 6, 5 2, 1 33, 34 37, 38 44, 43 48, 47 22, 23 58 56 59 57 24, 25 20, 19, 62, 61 27, 29, 52, 54 Description Differential input signal used for 1:4 signal fanout. Differential input signals used for 1:1 signal fanout.
Differential output signals.
Differential input signals used to select the input signal source. Serial data input. Clock used to latch in SDI. Chip select. Digital input which loads the delay registers. Terminals of an on-chip thermal diode string. External op amp compensation pins. Falling edge adjust DAC outputs. For test purposes only; nothing should be connected to these pins. Fine delay DAC outputs. For test purposes only; nothing should be connected to these pins.
DAC_FINE_(0-3)
28, 30, 51, 53
VCC
3, 4, 13, 14, 26, Positive power supply. 31, 35, 36, 40, 45, 46, 50, 55 7, 10, 17, 18, 21, Negative power supply. 32, 39, 41, 42, 49, 60, 63, 64
VEE
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Edge629
TEST AND MEASUREMENT PRODUCTS PIN Description (continued)
64 IN3* IN3 VCC3 VCC2 IN2* IN2 VEE2 IN* IN VEE1 IN1 IN1* VCC1 VCC0 IN0 IN0* 17 1
VEE3 VEE5 COMP2 COMP3 VEE5 CS SDI UPDATE CK VCC5 DAC_FALL_3 DAC_FINE_3 DAC_FALL_2 DAC_FINE_2 VCC5 VEE3
49 OUT3 OUT3* VCC3 VCC2 OUT2 OUT2* VEE2 VEE4 VCC4 VEE1 OUT1* OUT1 VCC1 VCC0 OUT0* 33 OUT0
E629AXF 64 Pin 10 mm x 10 mm TQFP Top View
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VEE0 VEE6 COMP1 COMP0 VEE6 SEL SEL* CATHODE ANODE VCC6 DAC_FALL_0 DAC_FINE_0 DAC_FALL_1 DAC_FINE_1 VCC6 VEE0
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Edge629
TEST AND MEASUREMENT PRODUCTS Circuit Description
Introduction The Edge629 is a quad channel delay element with 2 basic operating modes: 1) Fanout - 1 signal in, 4 signals out 2) Pass Through - 4 signals in, 4 signals out In all modes, each channel supports 3 delay functions: 1) Coarse timing delay 2) Fine timing delay 3) Falling edge adjust All 3 delay functions are independent of each other, and independent for each channel. The programming of the delay functions is done using a 16 bit register, loaded serially, which contains both a delay and an address value. Coarse Delay Coarse propagation delay adjustment is accomplished using a series of gate delays and multiplexers (see Figure 1). Coarse delay provides a total delay span of: 1 Coarse LSB = 90 ps 2 Coarse LSB = 180 ps 4 Coarse LSB = 360 ps 8 Coarse LSB = 720 ps 16 Coarse LSB = 1.44 ns 32 Coarse LSB = 2.88 ns 0 ns Coarse Delay Range 5.67 ns Each channel has its own unique coarse delay setting and may be programmed independently from all other channels. The coarse delay of any channel will not affect the fine delay of that channel, nor will it affect the overall delay of any other channel. The propagation delay of a rising edge and falling edge will track each other over the entire coarse delay span. (Adding or subtracting coarse delay does not cause pulse width distortion.)
Delay Code 000000 111111 Minimum Delay Maximum Delay 0.0 ns 5.67 ns
90 ps 180 ps 360 ps 720 ps 1.44 ns 2.88 ns
LSB
MSB
Coarse Delay Register 16 Bit Serial Register
0
1
2
3
4
Figure 1. Coarse Delay Architecture
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Edge629
TEST AND MEASUREMENT PRODUCTS Circuit Description (continued)
Fine Delay Fine delay is accomplished using an analog delay cell and an on-chip 6 bit DAC (see Figure 2). The fine delay range is designed to be ~2X the coarse delay resolution. Fine delay provides a total delay span of: LSB 1 Fine LSB = 2.5 ps (see note) 2 Fine LSB = 5 ps 4 Fine LSB = 10 ps 8 Fine LSB = 20 ps 16 Fine LSB = 40 ps MSP 32 Fine LSB = 80 ps 0 ns Fine Delay Range 157.5 ps. Note: Because the transfer function is non-linear, some LSB steps could be as large as 5 ps. Each channel has its own unique delay setting and may be programmed independently from all other channels. The fine delay of any channel will not affect the coarse delay of that channel, nor will it affect the overall delay of any other channel. The propagation delay of a rising and falling edge will track each other over the entire span of fine delay. (Adding or subtracting fine delay will not cause pulse width distortion.) Fine Delay Select The fine delay section may be selected or bypassed by a multiplexer (see Figure 2). If SFD (Select Fine Delay) is high, Fine Delay will be used. If SFD is low, Fine Delay will be bypassed.
DAC Code XXXXXX 000000 111111 SFD 0 1 1 Delay Fine Delay Bypassed Minimum Delay (0.0 ns) Maximum Delay (157 ps)
Fine Delay DAC Outputs DAC_FINE_(0-3) are analog voltage outputs from the onboard DACs which program the fine delay elements of each channel. DAC_FINE_(0-3) pins are for test purposes only. Nothing should be connected to these pins.
6 Bit DAC
T
SFD
Figure 2. Fine Delay Architecture
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Edge629
TEST AND MEASUREMENT PRODUCTS Circuit Description (continued)
Falling Edge Adjustment The falling edge of a signal may be adjusted to compensate for any system level pulse width distortion that may occur. Falling edge adjust (FEA) is accomplished using an analog delay cell and an on-chip 7 bit DAC (see Figure 3). FEA may be bypassed completely by a multiplexer. Also, FEA affects only the propagation delay of the falling edge. It has no effect on the propagation delay of a rising edge. Each channel has its own unique FEA setting and may be programmed independently from all other channels. The FEA of any channel will not affect the propagation delay of any other channel, nor will FEA affect the propagation delay of a rising edge.
Falling Edge Delay FEA Bypassed -250 ps +250 ps
There is a limitation on FEA range vs. pulse width.
Input Pulse Width 1.0 ns 900 ps 800 ps 700 ps 600 ps 500 ps FEA Range 250 ps 250 ps 250 ps 250 ps 200 ps 100 ps
Falling Edge Adjust DAC Outputs DAC_FALL_(0-3) are analog voltage outputs from the onboard DACs which program the falling edge delay elements of each channel. DAC_FALL_(0-3) pins are for test purposes only. Nothing should be connected to these pins. Thermal Monitor The Edge629 features a thermal diode string consisting of 5 diodes as shown in Figure 4 below. This string allows accurate die temperature measurements.
ANODE
SFE
DAC Code
Resolution
0 1 1
XXXXXXX 0000000 1111111
N/A 2.5 ps 2.5 ps
7 Bit DAC
Bias Current
T
Temperature Coefficient = -7.8 mV/C
CATHODE
SFE
Figure 4. Thermal Diode String Figure 3. Falling Edge Adjust Architecture
When an external bias current of up to 100 A is injected through the string, the voltage measured across the ANODE and CATHODE pins maps directly to the Edge629 junction temperature (see Figure 5).
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Edge629
TEST AND MEASUREMENT PRODUCTS Circuit Description (continued)
Programming The Edge629 is programmed serially with 3 control lines: SDI - serial data input CS - chip select UPDATE - register update which are all synchronous with CK. With CS valid (high), rising edge of CK will load SDI into the 16 bit shift register. With CS valid and UPDATE valid (high), CK high will make the selected latch go transparent. The falling edge of CK will then latch the data (see Figures 6 and 7). Data and address information are combined in the 16 bit word. Bits 0-6 are used for data, bits 11-15 for address. Bits 11-14 select 1 of 16 destinations, bit 15, if high, selects all 16 locations to be loaded simultaneously (useful for preloading all registers to a default state).
Bit Addr 0 1 2 3 4 5 6 7 8 9 A B C D E F X X 15 LA 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 14 A3 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 X X 13 A2 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 X X 12 A1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 X X 11 A0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 X X X 1 1 X X 1 1 X X 1 1 X X 1 1 X 0 1 10 Delay Function Channel 0, Coarse Delay Channel 0, Fine Delay Channel 0, Falling Edge Adjust Not Used Channel 1, Coarse Delay Channel 1, Fine Delay Channel 1, Falling Edge Adjust Not Used Channel 2, Coarse Delay Channel 2, Fine Delay Channel 2, Falling Edge Adjust Not Used Channel 3, Coarse Delay Channel 3, Fine Delay Channel 3, Falling Edge Adjust Not Used All Channels, Coarse Delay All Channels, All Functions
V = Vanode - Vcathode; Vcathode = VEE 4.20
4.00
3.80
3.60
V = Vanode - Vcathode [V]
3.40 : : : IFORCE = 100/Anode IFORCE = 10/Anode IFORCE = 1/Anode
3.20
3.00
2.80
2.60
2.40
2.20 0.00
50.0 Temp (C)
100
150
Figure 5. Voltage vs. Temperature for Thermal Diode String
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Edge629
TEST AND MEASUREMENT PRODUCTS Circuit Description (continued)
629 Digital Interface Timing 16 Bit Loads
CK0 CK15
CK
...
CD0 CD1 CD2 CD3 CD4 CD5 A0 A1 A2 A3 LA Load All
...
Coarse Delay Update
SDI
SDI
FD0
FD1
FD2
FD3
FD4
FD5
SFD
A0
A1
A2
A3
LA Load All
Fine Delay Update
SDI
FE0
FE1
FE2
FE3
FE4
FE5
FE6
SFE
A0
A1
A2
A3
LA Load All
Falling Edge Adjust Update
CS
UPDATE
Update Selected Delay Register
Figure 6. Synchronous Loading
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Edge629
TEST AND MEASUREMENT PRODUCTS Circuit Description (continued)
Coarse Delay 0
MSB LSB
5
4
3
2
1
0
Fine Delay
Channel 0
1
SFD
MSB
LSB
10
5
4
3
2
1
0
Falling Edge Adjust 2
SFE MSB LSB
10
6
5
4
3
2
1
0
Channel 1
Channel 2
. . . . . .
C
. . . . . .
. . . . . .
Coarse Delay
MSB LSB
5
4
3
2
1
0
Fine Delay
Channel 3
D
SFD
MSB
LSB
10
5
4
3
2
1
0
Falling Edge Adjust E
SFE MSB LSB
10
6
5
4
3
2
1
0
UPDATE
CS CK SDI
LA A3 A2 A1 A0 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
Address
Figure 7. Data Interface
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Edge629
TEST AND MEASUREMENT PRODUCTS Circuit Description (continued)
Timing Inputs IN/IN* and IN0/IN0* - IN3/IN3* are high speed differential inputs which require >300 mV of differential input voltage for reliable switching. These inputs may receive differential input signals with amplitudes up to 3.3V. This wide range input voltage compliance allows CMOS signals to drive the Edge629 directly. The inputs may go all the way up to VCC and still not cause any saturation. The Edge629 will operate at full performance under these input conditions. Do not leave any differential inputs floating as they will be in an indeterminate state. All unused inputs must be tied to either a high or low level. Connecting unused timing inputs to VCC is an acceptable method to make an input high. However, to make an input low, it must be connected to VEE +2.0V or higher. Input Mux Select
VCC VCC 50K CS 50K VEE
Data Interface Digital Inputs All data digital inputs are standard, single ended ECL inputs with Vbb = -1.3V relative to VCC. However, all digital inputs may receive input signals anywhere between VCC and VEE. This wide input voltage compliance allows CMOS signals to program the Edge629 without causing saturation problems. All digital interface inputs are "3.3V rail to rail" CMOS compatible provided VCC = +3.3V and VEE = -2V. CK, SDI, and UPDATE all have an internal pull-down resistor network to establish a default condition of a logical 0 when left floating. CS has a large (~50 K) internal pullup resistor to VCC to establish a default condition of a logical 1 when left floating. For optimal performance, all data interface digital inputs should be static when the Edge 629 is actively delaying signals. (However, it is acceptable if CK continues to run.)
Each delay channel can select its input from one of two sources. If Mux Select is high (SEL > SEL*), IN/IN* will be selected for all four channels. If Mux Select is low (SEL < SEL*), IN0/IN0* - IN3/IN3* will be selected for each channel.
SEL/SEL* 0 1 Input Source IN0/IN0* - IN3/IN3* IN/IN* Mode Pass Through Fanout
50K CK, SDI, UPDATE
Timing Outputs OUT0/OUT0* - OUT3/OUT3* are standard differential ECL open emitter outputs. Compensation Pins COMP0, COMP1, COMP2, and COMP3 are op amp compensation pins requiring external 100 pF capacitors to VEE.
SEL/SEL* have internal pull-up/pull-down resistors which, when left floating, place the chip in fanout mode.
VCC VCC 50K SEL SEL* 50K VEE
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Edge629
TEST AND MEASUREMENT PRODUCTS Package Information
64-Pin TQFP 10 mm x 10 mm x 1.4 mm
D
PIN Descriptions
D1
N
12 TYP .
EXPOSED HEATSINK 3.56 .50 DIA.
1
A2 A1
A
-A-
-B-
E1
E
12 TYP .
-D-
Top View
Dims.
.20 RAD. TYP .
Tolerance MAX.
Value 1.60 .05 min. / .15 max
A A1
20 RAD. TYP .
A2 D
.05 .20 .10 .20 .10 +.15 / -.10 BASIC .05
1.40 12.00 10.00 12.00 10.00 .60 .50 .22 0 - 7
64 STANDOFF
A
A1
.25 SEATING PLANE
D1 E
.17 MAX
L
b
ddd M C A-B S D S
-C-
LEAD COMPLANARITY
ccc C
E1 L e b ddd ccc Package Thickness Footprint
Notes: 1. All dimensions in millimeters. 2. Dimensions shown are nominal with tolerances as indicated. 3. L/F: EFTEC 64T copper or equivalent, 0.127mm (.005") or 0.15mm (.006") thick. 4. Foot length "L" is measured at gage plane, at 0.25 above the seating plane.
2005 Semtech Corp. Rev. 3, 8/1/05
MAX. MAX.
.08 .08 1.40 Body + 2 mm
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Edge629
TEST AND MEASUREMENT PRODUCTS Recommended Operating Conditions
Parameter Total Power Supply Junction Temperature Symbol VCC - VEE TJ Min 4.2 0 Typ 5.2 Max +5.5 +100 Units V C
Absolute Maximum Ratings
Parameter Power Supply Voltage on any Digital Input Pin Voltage on any Analog Input Pin Output Current Storage Temperature Junction Temperature Soldering Temperature (5 seconds, .25" from the pin) JC (to top of case) J A (@ still air) J A (@ 400 LFPM) TS TJ TSOL J C J A J A Symbol VCC - VEE Min 0 VEE - 0.5 VEE - 0.5 -50 -65 +150 +150 +260 Typ Max 7.0 VCC + 0.5 VCC + 0.5 Units V V V mA C C C
1.5 28 21
C C C
Stresses above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only, and functional operation of the device at these, or any other conditions beyond those listed, is not implied. Exposure to absolute maximum conditions for extended periods may affect device reliability.
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Edge629
TEST AND MEASUREMENT PRODUCTS DC Characteristics
Parameter Timing Inputs (IN/IN*, IN0/IN0* - IN3/IN3*) Differential Input Voltage Input High Voltage Range Input Low Voltage Range Input High Current Input Low Current Select Input (SEL/SEL*) Input High Voltage Input Low Voltage Input High Common Mode Range Input Low Common Mode Range Input High Current Input Low Current Programming Inputs (CK, UPDATE, CS, SDI) Input High Voltage Input Low Voltage Input High Current Input Low Current Digital Outputs Digital Output High Voltage Digital Output Low Voltage Output Common Mode Range Output Current Power Supply Current VCC - VEE = 4.2V VCC - VEE = 5.2V VCC - VEE = 5.5V IEE IEE IEE 561 604 613 900 900 900 mA mA mA OUT - OUT* OUT* - OUT OUT + OUT* 2 Iout 600 600 VCC - 1.5 690 690 VCC - 1.3 VCC - 1.1 30 mV mV V mA VIH VIL IIH IIL VCC - 1.1 VEE + 2.0 VCC VCC - 1.5 250 250 V V A A SEL - SEL* SEL* - SEL VIH VIL IIH IIL .3 .3 VEE + 2.0 VEE + 2.0 VCC - VEE VCC - VEE VCC VIH - .3 250 250 V V V V A A |IN - IN*| VIH VIL IIH IIL .3 VEE + 2.0 VEE + 2.0 -100 -100 VCC - VEE VCC VIH - .3 +100 +100 V V V A A Symbol Min Typ Max Units
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Edge629
TEST AND MEASUREMENT PRODUCTS AC Characteristics
Parameter Timing Inputs/Outputs Minimum Propagation Delay (Note 2) IN to OUT (0,3) IN0, 3 to OUT (0,3) Tpd, FD Disabled to FD=0 Tpd, FEA Disabled to FEA=0 Rising Edge/Falling Edge Propagation Delay Difference (FEA disabled) Channel-to-Channel Skew (Note 2) IN to OUT (0,3) (Fanout Mode) IN (0,3) to OUT (0,3) Programmable Delay (Note 2) Coarse Delay Fine Delay Falling Edge Adjust (SFE = 1) (Note 1) Programmable Delay Step Size (Note 3) Coarse Delay Fine Delay Falling Edge Adjust Maximum Operating Frequency (FEA Enabled) Maximum Operating Frequency (FEA Disabled) Minimum Pulse Width (at outputs) Output Rise and Fall Times (20% - 80%) Tpd Min Tpd Min Tpd Tpd |Tpd+ - Tpd-| 1.282 1.406 1.357 1.481 320 950 3 1.432 1.556 ns ns ps ps ps Symbol Min Typ Max Units
10
Tskew1 Tskew2 Tspan_Coarse Tspan_Fine FEA 5.5 110 200
10 15 6.0 150 250
45 50 6.5 180 300
ps ps ns ps ps
Tstep_Coarse Tstep_Fine Tstep_FEA Fmax Fmax PW min Tr/Tf Tpd/T
1.0 1.0 1.0 1.0 1.3 350
95 5 5
110 7 7
ps ps ps GHz GHz ps
110
150
ps
Temperature Coefficient (vs. Die Temp) CD = Min, FD & FEA Disabled CD = Max, FD & FEA Disabled CD & FD = Min, FEA Disabled CD & FD = Max, FEA Disabled CD, FD, & FEA = Min CD, FD, & FEA = Max Total Timing Error Tpd vs. Frequency Channel-to-Channel Crosstalk Tpd vs. Duty Cycle Jitter @ Minimum Delay Jitter @ Maximum Delay
2.4 13.3 3.3 15.1 5.2 18.8
ps/C ps/C ps/C ps/C ps/C ps/C
20 2 20
10 1 5
ps ps ps ps
Test Conditions (unless otherwise specified): "Recommended Operating Conditions."
2005 Semtech Corp. Rev. 3, 8/1/05 14 www.semtech.com
Edge629
TEST AND MEASUREMENT PRODUCTS AC Characteristics (continued)
Test Conditions (unless otherwise specified): "Recommended Operating Conditions." Note 1: Tested with an input pulse = 50 ns. This parameter is guaranteed by characterization for input pulse widths 700 ps. Note 2: Coarse Delay = 0, Fine Delay and Falling Edge Adjust disabled. Case Temperature = 50C. Note 3: Coarse Delay is monotonic. Fine Delay is Monotonic. Since the fine delay spans close to 2 LSBs of coarse delay, the summation of digital codes for coarse and fine delays is not monotonic. Proper binary searching using both the coarse and fine delays is achieved first with the coarse (with SFD=1), and then with the fine delays as separate searches.
Parameter Data Interface Set Up Time SDI to CK CS to CK UPDATE to CK Hold Time CK to SDI CK to CS CK to UPDATE Minimum Pulse Widths CK High CK Low CK Period DAC Settling Time
Symbol
Min
Typ
Max
Units
Tsu Tsu Tsu Th Th Th
10 10 20 4 4 4 13 13 30 1
ns ns ns ns ns ns ns ns ns s
T
Test Conditions (unless otherwise specified): "Recommended Operating Conditions." AC Characteristics are guaranteed by design and characterization. Not production tested.
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Edge629
TEST AND MEASUREMENT PRODUCTS Ordering Infor mation
Model Number
Package 10 x 10 x 1.4mm TQFP w/Exposed Heatsink on Top Edge629 Evaluation Board
E629AXF
EVM629AXF
Contact Infor mation
Semtech Corporation Test and Measurement Division 10021 Willow Creek Rd., San Diego, CA 92131 Phone: (858)695-1808 FAX (858)695-2633
2005 Semtech Corp. Rev. 3, 8/1/05 16 www.semtech.com

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