streamª 33 17, 3.2 Gb/s a FUNCTIONAL BLOCK DIAGRAM INP INN CS RE 7 5 A WE FIRST RANK 17 7-BIT LATCH SECOND RANK 17 7-BIT LATCH INPUT DECODERS D 33 OUTPUT ADDRESS DECODER FEATURES Low Cost 33 17, Fully Differential, Nonblocking Array 3.2 Gb/s per Port NRZ Data Rate Wide Power Supply Range: +3.3 V, –3.3 V Low Power 425 mA (Outputs Enabled) 35 mA (Outputs Disabled) LV PECL and LV ECL Compatible CMOS/TTL-Level Control Inputs: 3 V to 5 V Low Jitter No Heat Sinks Required Drives a Backplane Directly Programmable Output Current Optimize Termination Impedance User-Controlled Voltage at the Load Minimize Power Dissipation Individual Output Disable for Busing and Reducing Power Double Row Latch Buffered Inputs Available in 184-Lead LQFP Digital Crosspoint Switch AD8151* 33 17 33 17 DIFFERENTIAL SWITCH 17 MATRIX OUTP OUTN AD8151 UPDATE RESET APPLICATIONS High-Speed Serial Backplane Routing to OC-48 with FEC Fiber Optic Network Switching Fiber Channel LVDS PRODUCT DESCRIPTION AD8151 is a member of the Xstream line of products and is a breakthrough in digital switching, offering a large switch array (33 × 17) on very little power, typically less than 1.5 W. Additionally, it operates at data rates in excess of 3.2 Gb/s per port, making it suitable for Sonet OC-48 with 8b/10b Forward Error Correction (FEC). Further, the pricing of the AD8151 makes it affordable enough to be used for lower data rates as well. The AD8151’s flexible supply voltages allow the user to operate with either PECL or ECL data levels and will operate down to 3.3 V for further power reduction. The control interface is CMOS/ TTL compatible (3 V to 5 V). Figure 1. Eye Pattern, 3.2 Gb/s, PRBS 23 Its fully differential signal path reduces jitter and crosstalk while allowing the use of smaller single-ended voltage swings. The AD8151 is offered in a 184-lead LQFP package that operates over the extended commercial temperature range of 0°C to 85°C. *Patent Pending. Xstream is a trademark of Analog Devices, Inc. REV. 0 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. 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 © Analog Devices, Inc., 2001 (@ 25C, VCC = 3.3 V to 5 V, VEE = 0 V, RL = 50 (see TPC 22), IOUT = 16 mA, unless AD8151–SPECIFICATIONS otherwise noted.) Parameter DYNAMIC PERFORMANCE Max Data Rate/Channel (NRZ) Channel Jitter RMS Channel Jitter Propagation Delay Propagation Delay Match Output Rise/Fall Time INPUT CHARACTERISTICS Input Voltage Swing Input Bias Current Input Capacitance Input VIN High Input VIN Low OUTPUT CHARACTERISTICS Output Voltage Swing Output Voltage Range Output Current Output Capacitance Output VOUT High Output VOUT Low POWER SUPPLY Operating Range PECL, VCC ECL, VEE VDD VSS Quiescent Current VDD VEE Conditions Typ 2.5 3.2 52 8 650 ± 50 100 Data Rate = 3.2 Gb/s Input to Output 20% to 80% Single-Ended 200 Max ± 100 1000 2 2 VCC – 1.2 VCC – 2.4 Differential (See TPC 22) VCC VCC – 1.4 800 VCC – 1.8 5 VCC 25 2 VCC – 1.8 VCC VEE = 0 V VCC = 0 V 3.0 –5.25 3 5.25 –3.0 5 0 2 425 All Outputs Enabled, IOUT = 16 mA TMIN to TMAX All Outputs Disabled THERMAL CHARACTERISTICS Operating Temperature Range θJA LOGIC INPUT CHARACTERISTICS Input VIN High Input VIN Low Min 450 35 0 Unit Gb/s ps p-p ps ps ps ps mV p-p µA pF V V mV p-p V mA pF V V V V V V mA mA mA mA 85 °C °C/W VDD 0.9 V V 30 VDD = 3 V dc to 5 V dc 1.9 0 –2– REV. 0 AD8151 ABSOLUTE MAXIMUM RATINGS 1 MAXIMUM POWER DISSIPATION Supply Voltage VDD – VEE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.5 V VCC – VEE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.5 V VDD – VSS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.5 V VSS – VEE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.5 V VSS – VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.5 V VDD – VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.5 V Internal Power Dissipation2 AD8151 184-Lead Plastic LQFP (ST) . . . . . . . . . . . . 4.2 W Differential Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . 2.0 V Storage Temperature Range . . . . . . . . . . . . –65°C to +125°C Lead Temperature Range (Soldering 10 sec) . . . . . . . . . 300°C The maximum power that can be safely dissipated by the AD8151 is limited by the associated rise in junction temperature. The maximum safe junction temperature for plastic encapsulated devices is determined by the glass transition temperature of the plastic, approximately 150°C. Temporarily exceeding this limit may cause a shift in parametric performance due to a change in the stresses exerted on the die by the package. Exceeding a junction temperature of 175°C for an extended period can result in device failure. To ensure proper operation, it is necessary to observe the maximum power derating curves shown in Figure 2. NOTES 1 Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 2 Specification is for device in free air (T A = 25°C): 184-lead plastic LQFP (ST): θJA = 30°C/W. 6.0 MAXIMUM POWER DISSIPATION – Watts TJ = 150C 5.0 4.0 3.0 2.0 1.0 –10 0 10 20 30 40 50 60 AMBIENT TEMPERATURE – C 70 80 90 Figure 2. Maximum Power Dissipation vs. Temperature ORDERING GUIDE Model Temperature Range Package Description Package Option AD8151AST 0°C to 85°C 184-Lead Plastic LQFP (20 mm × 20 mm) Evaluation Board ST-184 AD8151-EVAL 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 AD8151 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. REV. 0 –3– WARNING! ESD SENSITIVE DEVICE AD8151 139 VEE 140 IN13P 142 VEE 141 IN13N 143 IN14P 145 VEE 144 IN14N 146 IN15P 148 VEE 147 IN15N 150 VEEREF 149 VCC 152 VSS 151 REF 153 D6 154 D5 155 D4 156 D3 157 D2 158 D1 159 D0 160 A4 161 A3 163 A1 162 A2 165 UPDATE 164 A0 167 RE 166 WE 169 RESET 168 CS 172 VEE 171 VCC 170 VDD 173 IN16P 175 VEE 174 IN16N 178 VEE 177 IN17N 176 IN17P 179 IN18P 181 VEE 180 IN18N 1 138 PIN 1 IDENTIFIER 2 3 4 137 136 135 134 5 6 133 7 132 8 131 9 130 10 11 129 128 12 13 127 126 14 15 125 16 123 17 122 121 124 18 19 120 119 20 21 22 118 AD8151 23 117 116 115 184L LQFP 24 TOP VIEW (Not to Scale) 25 114 26 27 113 28 111 29 110 30 109 31 32 108 112 107 106 33 34 35 105 104 36 103 37 102 38 39 101 40 99 41 98 42 44 97 96 95 45 94 46 93 100 92 91 90 89 88 87 85 86 84 83 81 82 80 79 78 77 76 75 74 73 72 71 70 69 67 68 66 65 64 62 63 61 60 59 58 57 56 55 53 54 52 51 50 49 48 47 43 VEE IN12N IN12P VEE IN11N IN11P VEE IN10N IN10P VEE IN09N IN09P VEE IN08N IN08P VEE IN07N IN07P VEE IN06N IN06P VEE IN05N IN05P VEE IN04N IN04P VEE IN03N IN03P VEE IN02N IN02P VEE IN01N IN01P VEE IN00N IN00P VEE VCC VEEA0 OUT00P OUT00N VEEA1 VEE VEE OUT15N OUT15P VEEA15 OUT14N OUT14P VEEA14 OUT13N OUT13P VEEA13 OUT12N OUT12P VEEA12 OUT11N OUT11P VEEA11 OUT10N OUT10P VEEA10 OUT09N OUT09P VEEA9 OUT08N OUT08P VEEA8 OUT07N OUT07P VEEA7 OUT06N OUT06P VEEA6 OUT05N OUT05P VEEA5 OUT04N OUT04P VEEA4 OUT03N OUT03P VEEA3 OUT02N OUT02P VEEA2 OUT01N OUT01P VEE VEE IN20P IN20N VEE IN21P IN21N VEE IN22P IN22N VEE IN23P IN23N VEE IN24P IN24N VEE IN25P IN25N VEE IN26P IN26N VEE IN27P IN27N VEE IN28P IN28N VEE IN29P IN29N VEE IN30P IN30N VEE IN31P IN31N VEE IN32P IN32N VEE VCC VEE OUT16N OUT16P VEEA16 VEE 182 IN19P 184 VEE 183 IN19N PIN CONFIGURATION –4– REV. 0 AD8151 PIN FUNCTION DESCRIPTIONS Pin No. Signal Type Description 1, 4, 7, 10, 13, 16, 19, 22, 25, 28, 31, 34, 37, 40, 42, 46, 47, 92, 93, 99, 102, 105, 108, 111, 114, 117, 120, 123, 126, 129, 132, 135, 138, 139, 142, 145, 148, 172, 175, 178, 181, 184 2 3 5 6 8 9 11 12 14 15 17 18 20 21 23 24 26 27 29 30 32 33 35 36 38 39 41, 98, 149, 171 VEE Power Supply Most Negative PECL Supply (Common with Other Points Labeled VEE) IN20P IN20N IN21P IN21N IN22P IN22N IN23P IN23N IN24P IN24N IN25P IN25N IN26P IN26N IN27P IN27N IN28P IN28N IN29P IN29N IN30P IN30N IN31P IN31N IN32P IN32N VCC PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL Power Supply 43 44 45 48 49 50 51 52 53 54 55 56 57 58 59 60 61 OUT16N OUT16P VEEA16 OUT15N OUT15P VEEA15 OUT14N OUT14P VEEA14 OUT13N OUT13P VEEA13 OUT12N OUT12P VEEA12 OUT11N OUT11P PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement Most Positive PECL Supply (Common with Other Points Labeled VCC) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to This Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output REV. 0 –5– AD8151 Pin No. Signal Type Description 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 94 95 96 97 100 101 103 104 106 107 109 110 112 113 115 116 118 119 121 122 VEEA11 OUT10N OUT10P VEEA10 OUT09N OUT09P VEEA9 OUT08N OUT08P VEEA8 OUT07N OUT07P VEEA7 OUT06N OUT06P VEEA6 OUT05N OUT05P VEEA5 OUT04N OUT04P VEEA4 OUT03N OUT03P VEEA3 OUT02N OUT02P VEEA2 OUT01N OUT01P VEEA1 OUT00N OUT00P VEEA0 IN00P IN00N IN01P IN01N IN02P IN02N IN03P IN03N IN04P IN04N IN05P IN05N IN06P IN06N IN07P IN07N Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL Power Supply PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Output Complement High-Speed Output Most Negative PECL Supply (Unique to this Output) High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement –6– REV. 0 AD8151 Pin No. Signal Type Description 124 125 127 128 130 131 133 134 136 137 140 141 143 144 146 147 150 IN08P IN08N IN09P IN09N IN10P IN10N IN11P IN11N IN12P IN12N IN13P IN13N IN14P IN14N IN15P IN15N VEEREF PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL R-Program 151 REF R-Program 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 173 174 176 177 179 180 182 183 VSS D6 D5 D4 D3 D2 D1 D0 A4 A3 A2 A1 A0 UPDATE WE RE CS RESET VDD IN16P IN16N IN17P IN17N IN18P IN18N IN19P IN19N Power Supply TTL TTL TTL TTL TTL TTL TTL TTL TTL TTL TTL TTL TTL TTL TTL TTL TTL Power Supply PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL PECL/ECL High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement Connection Point for Output Logic Pull-Down Programming Resistor (Must be Connected to VEE) Connection Point for Output Logic Pull-Down Programming Resistor Most Negative Control Logic Supply Enable/Disable Output (32) MSB Input Select (16) (8) (4) (2) (1) LSB Input Select (16) MSB Output Select (8) (4) (2) (1) LSB Output Select Second Rank Program First Rank Program Enable Readback Enable Chip to Accept Programming Disable All Outputs (Hi-Z) Most Positive Control Logic Supply High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement High-Speed Input High-Speed Input Complement REV. 0 –7– AD8151–Typical Performance Characteristics TPC 4. Eye Pattern 3.2 Gb/s, PRBS 23 TPC 1. Eye Pattern 2.5 Gb/s, PRBS 23 p-p = 43ps STD DEV = 8ps 150mV/DIV 150mV/DIV p-p = 53ps STD DEV = 8ps 20ps/DIV 20ps/DIV TPC 5. Jitter @ 3.2 Gb/s, PRBS 23 100 100 90 90 80 80 70 70 EYE HEIGHT – % EYE WIDTH – % TPC 2. Jitter @ 2.5 Gb/s, PRBS 23 60 % EYE WIDTH = 50 (CLOCK PERIOD – JITTER p-p) CLOCK PERIOD 100 40 60 % EYE HEIGHT = 50 (VOUT @ DATA RATE) VOUT @ 0.5Gb/s 100 40 30 30 20 20 10 10 0 0 0.5 1.0 1.5 2.0 2.5 3.0 0.5 3.5 1.0 1.5 2.0 2.5 3.0 3.5 DATA RATE – Gb/s DATA RATE – Gb/s TPC 3. Eye Width vs. Data Rate, PRBS 23 TPC 6. Eye Height vs. Data Rate, PRBS 23 –8– REV. 0 AD8151 100 90 90 80 80 70 70 JITTER – ps 100 JITTER – ps 60 50 PEAK-PEAK JITTER 40 60 40 30 30 20 20 10 0 1.0 2.0 2.5Gb/s JITTER 3.2Gb/s STD DEV STANDARD DEVIATION 1.5 3.2Gb/s JITTER 50 10 2.5 3.0 2.5Gb/s STD DEV 0 3.5 0 10 20 30 40 50 60 70 80 90 TEMPERATURE – C DATA RATE – Gb/s TPC 10. Jitter vs. Temperature, PRBS 23 TPC 7. Jitter vs. Data Rate, PRBS 23 150mV/DIV 150mV/DIV p-p = 38ps STD DEV = 7.7ps p-p = 32ps STD DEV = 4.7ps 100ps/DIV 75ps/DIV TPC 8. Crosstalk, 2.5 Gb/s, PRBS 23, Attack Signal is OFF TPC 11. Crosstalk, 3.2 Gb/s, PRBS 23, Attack Signal is OFF 150mV/DIV 150mV/DIV p-p = 70ps STD DEV = 8ps p-p = 70ps STD DEV = 9ps 75ps/DIV 100ps/DIV TPC 9. Crosstalk, 2.5 Gb/s, PRBS 23, Attack Signal is ON REV. 0 TPC 12. Crosstalk, 3.2 Gb/s, PRBS 23, Attack Signal is ON –9– 150mV/DIV 150mV/DIV AD8151 1.1ns/DIV 1.4ns/DIV TPC 16. Response, 3.2 Gb/s, 32-Bit Pattern 1111 1111 0000 0000 0101 0101 0011 0011 TPC 13. Response, 2.5 Gb/s, 32-Bit Pattern 1111 1111 0000 0000 0101 0101 0011 0011 100 100 90 90 80 80 70 70 P-P JITTER – ps P-P JITTER – ps 3.2Gb/s 60 2.5Gb/s JITTER 50 40 60 50 2.5Gb/s 40 30 30 3.2Gb/s JITTER 20 20 10 10 0 0.2 0.3 0.4 0.5 0.6 0.7 INPUT AMPLITUDE – V 0.8 0.9 0 –5.0 1 TPC 14. Jitter vs. Single-Ended Input Amplitude, PRBS 23 100 90 90 80 80 70 2.5Gb/s P-P JITTER – ps P-P JITTER – ps 70 60 3.2Gb/s 50 40 –3.6 –3.4 –3.2 –3.0 20 10 0 –1.4 0.6 3.2Gb/s 2.5Gb/s 10 TPC 15. Jitter vs. VIH, PRBS 23 –4.0 –3.8 VEE – V 40 20 0.4 –4.2 50 30 0.2 –4.4 60 30 0 –4.6 TPC 17. Jitter vs. Supply, PRBS 23 100 0 –1.6 –1.4 –1.2 –1.0 –0.8 –0.6 –0.4 –0.2 VIH – V –4.8 –1.2 –1.0 –0.8 –0.6 –0.4 VOH – V –0.2 0 0.2 TPC 18. Jitter vs. VOH, PRBS 23, Output Amplitude = 0.4 V Single-Ended –10– REV. 0 AD8151 100 200 90 150 PROPAGATION DELAY – ps 80 FREQUENCY 70 60 50 40 30 20 100 50 0 –50 –100 –150 10 0 550 570 590 610 630 650 670 690 PROPAGATION DELAY – ps 710 –200 –100 730 –80 –60 –40 –20 0 20 40 60 80 100 NORMALIZED TEMPERATURE – C TPC 21. Propagation Delay, Normalized at 25 °C vs. Temperature TPC 19. Variation in Channel-to-Channel Delay, All 561 Points 100 VCC 90 PRBS GENERATOR 80 P-P JITTER – ps 70 DATA OUT 49.9 AD8151 P –6dB 105 DATA OUT 50 IN P OUT N –6dB N 50 3.2Gb/s 40 49.9 1.65k VEE VEE 20 VTT VCC = 0V, VEE = –3.3V, VTT = –1.6V, VDD = 5V, VSS = 0V RSET = 1.54k, IOUT = 16mA, VOH = –0.8V, VOL = –1.2V 10 0 HIGH-SPEED SAMPLING OSCILLOSCOPE 50 2.5Gb/s 60 30 VIN = 0.8V p-p EXCEPT AS NOTED 5 10 15 20 OUTPUT CURRENT – mA 25 TPC 22. Test Circuit TPC 20. Jitter vs. IOUT, PRBS 23 REV. 0 1.65k VTT VCC –11– AD8151 Control Interface Truth Tables The following are truth tables for the control interface. Table I. Basic Control Functions RESET CS Control Pins WE RE UPDATE 0 1 X 1 X X X X X X 1 0 0 X X 1 0 X 0 X 1 0 X X 0 1 0 0 1 0 Function Global Reset. Reset all second rank enable bits to zero (disable all outputs). Control Disable. Ignore all logic (but the signal matrix still functions as programmed). D[6:0] are high-impedance. Single Output Preprogram. Write input configuration data from data bus D[6:0]. into first rank of latches for the output selected by the output address bus A[4:0]. Single Output Readback. Readback input configuration data from second rank of latches onto data bus D[6:0] for the single output selected by the output address bus A[4:0]. Global Update. Copy input configuration data from all 17 first rank latches into second rank of latches, updating signal matrix connections for all outputs. Transparent Write and Update. It is possible to write data directly onto rank two. This simplifies logic when synchronous signal matrix updating is not necessary. Table II. Address/Data Examples Output Address Pins MSB–LSB Enable Bit Input Address Pins MSB–LSB A4 A3 A2 A1 A0 D6/E D5 D4 D3 D2 D1 D0 Function 0 0 0 0 0 X 0 0 0 0 0 0 Lower Address/Data Range. Connect Output #00 (A[4:0] = 00000) to Input #00 (D[5:0] = 000000). 1 0 0 0 0 X 1 0 0 0 0 0 Upper Address/Data Range. Connect Output #16 (A[4:0] = 10000) to Input #32 (D[5:0] = 100000). <Binary Output Number*> 1 <Binary Output Number*> 0 1 0 0 0 1 X 1 0 0 1 0 X <Binary Input Number> X X X X X Enable Output. Connect Selected Output (A[4:0] = 0 to 16) to Designated Input (D[5:0] = 0 to 32) and Enable Output (D6 = 1). X <Binary Input Number> 1 0 0 0 0 Disable Output. Disable Specified Output (D6 = 0). Broadcast Connection. Connect all 17 outputs to same designated input and set all 17 enable bits to the value of D6. Readback is not possible with the broadcast address. 1 Reserved. Any address or data code greater or equal to these are reserved for future expansion or factory testing. *The binary output number may also be the broadcast connection designator, 10001. –12– REV. 0 AD8151 Control Interface Timing Diagrams CS INPUT WE INPUT A[4:0] INPUTS D[6:0] INPUTS tCSW tCHW tASW tAHW tWP tDSW tDHW Figure 3. First Rank Write Cycle Table III. First Rank Write Cycle Symbol Parameter tCSW tASW tDSW Setup Time Chip Select to Write Enable Address to Write Enable Data to Write Enable tCHW tAHW tDHW Hold Time Chip Select from Write Enable Address from Write Enable Data from Write Enable tWP Width of Write Enable Pulse Conditions Min Typ Max Unit TA = 25°C VDD = 5 V VCC = 3.3 V 0 0 15 ns ns ns 0 0 0 ns ns ns 15 ns CS INPUT UPDATE INPUT ENABLING OUT[0:16][N:P] OUTPUTS DATA FROM RANK 1 TOGGLE OUT[0:16][N:P] OUTPUTS PREVIOUS RANK 2 DATA DISABLING OUT[0:16][N:P] OUTPUTS DATA FROM RANK 2 tCSU DATA FROM RANK 1 tCHU tUW tUOE tUOD tUOT Figure 4. Second Rank Update Cycle Table IV. Second Rank Update Cycle Symbol Parameter tCSU tCHU tUOE tUOT tUOD Setup Time Hold Time Output Enable Times Output Toggle Times Output Disable Times tUW Width of Update Pulse REV. 0 Chip Select to Update Chip Select from Update Update to Output Enable Update to Output Reprogram Update to Output Disabled Conditions Min TA = 25°C VDD = 5 V VCC = 3.3 V 0 0 25 25 25 15 –13– Typ Max Unit 40 40 30 ns ns ns ns ns ns AD8151 CS INPUT UPDATE INPUT WE INPUT ENABLING OUT[0:16][N:P] OUTPUTS DISABLING OUT[0:16][N:P] OUTPUTS INPUT {DATA 1} INPUT {DATA 2} INPUT {DATA 1} INPUT {DATA 0} tCSU tCHU tUW tUOT tWOT tUOE tWHU tWOD Figure 5. First Rank Write Cycle and Second Rank Update Cycle Table V. First Rank Write Cycle and Second Rank Update Cycle Symbol Parameter Conditions Min 0 0 tCSU tCHU Setup Time Hold Time Chip Select to Update Chip Select from Update TA = 25°C VDD = 5 V tUOE tWOE* Output Enable Times Update to Output Enable Write Enable to Output Enable VCC = 3.3 V tUOT tWOT Output Toggle Times tUOD* tWOD Typ Max Unit ns ns 25 25 40 40 ns ns Update to Output Reprogram Write Enable to Output Reprogram 25 25 30 30 ns ns Output Disable Times Update to Output Disabled Write Enable to Output Disabled 25 25 30 30 ns ns tWHU Setup Time Write Enable to Update tUW Width of Update Pulse 10 ns 15 ns *Not Shown. CS INPUT RE INPUT A[4:0] INPUTS ADDR 1 ADDR 2 DATA {ADDR1} D[6:0] OUTPUTS DATA {ADDR2} tCSR tRDE tAA tCHR tRHA tRDD Figure 6. Second Rank Readback Cycle Table VI. Second Rank Readback Cycle Symbol Parameter Conditions Min 0 0 5 tCSR tCHR tRHA Setup Time Hold Time Chip Select to Read Enable Chip Select from Read Enable Address from Read Enable TA = 25°C VDD = 5 V VCC = 3.3 V tRDE tAA tRDD Enable Time Access Time Release Time Data from Read Enable Data from Address Data from Read Enable 10 kΩ 20 pF on D[6:0] Bus –14– Typ Max Unit ns ns ns 15 15 15 30 ns ns ns REV. 0 AD8151 RESET INPUT DISABLING OUT[0:16][N:P] OUTPUTS tTOD tTW Figure 7. Asynchronous Reset Table VII. Asynchronous Reset Symbol tTOD tTW Parameter Disable Time Width of Reset Pulse Output Disable from Reset Conditions Min TA = 25°C VDD = 5 V VCC = 3.3 V 15 Typ Max Unit 25 30 ns ns Control Interface Programming Example The following conservative pattern connects all outputs to input number 7, except output 16 which is connected to input number 32. The vector clock period, T0 is 15 ns. It is possible to accelerate the execution of this pattern by deleting vectors 1, 4, 7, and 9. Table VIII. Basic Test Pattern Vector No. RESET CS WE RE UPDATE A[4:0] D[6:0] Comments 0 1 2 3 4 5 6 7 8 9 10 0 1 1 1 1 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1 0 1 1 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 1 1 xxxxx xxxxx 10001 10001 10001 10000 10000 10000 xxxxx xxxxx xxxxx xxxxxxx xxxxxxx 1000111 1000111 1000111 1100000 1100000 1100000 xxxxxxx xxxxxxx xxxxxxx Disable All Outputs REV. 0 –15– All Outputs to Input #07 Write to First Rank Output #16 to Input #32 Write to First Rank Transfer to Second Rank Disable Interface AD8151 7 UPDATE RESET 7 7 7 7 7 7 D[0:6] 0 0 1 1 2 2 7 CONTROL PIN DESCRIPTION A[4:0] Inputs TO 1733 SWITCH MATRIX 33 7 7 7 33 7 7 33 7 33 Output address pins. The binary encoded address applied to these five input pins determines which one of the seventeen outputs is being programmed (or being read back). The most significant bit is A4. D[6:0] Inputs/Outputs 7 7 16 16 RANK 1 RANK 2 7 17 ROWS OF 7-BIT LATCHES Input configuration data pins. In write mode, the binary encoded data applied to pins D[6:0] determine which one of 33 inputs is to be connected to the output specified with the A[4:0] pins. The most significant bit is D5, and the least significant bit is D0. Bit D6 is the enable bit, setting the specified output signal pair to an enabled state if D6 is logic HIGH, or disabled to a high-impedance state if D6 is logic LOW. 1 OF 33 DECODERS WE In readback mode, pins D[6:0] are low-impedance outputs indicating the data word stored in the second rank for the output specified with the A[4:0] pins. The readback drivers were designed to drive high impedances only, so external drivers connected to the D[6:0] should be disabled during readback mode. 1 OF 17 DECODERS A[0:4] RE WE Input Figure 8. Control Interface (Simplified Schematic) AD8151 CONTROL INTERFACE The AD8151 control interface receives and stores the desired connection matrix for the 33 input and 17 output signal pairs. The interface consists of 17 rows of double-rank 7-bit latches, one row for each output. The 7-bit data word stored in each of these latches indicates to which (if any) of the 33 inputs the output will be connected. One output at a time can be preprogrammed by addressing the output and writing the desired connection data into the first rank of latches. This process can be repeated until each of the desired output changes has been preprogrammed. All output connections can then be programmed at once by passing the data from the first rank of latches into the second rank. The output connections always reflect the data programmed into the second rank of latches, and do not change until the first rank of data is passed into the second rank. If necessary for system verification, the data in the second rank of latches can be read back from the control interface. At any time, a reset pulse can be applied to the control interface to globally reset the appropriate second rank data bits, disabling all 17 signal output pairs. This feature can be used to avoid output bus contention on system start-up. The contents of the first rank remain unchanged. The control interface pins are connected via logic-level translators. These translators allow programming and readback of the control interface using logic levels different from those in the signal matrix. In order to facilitate multiple chip address decoding, there is a chip-select pin. All logic signals except the reset pulse are ignored unless the chip select pin is active. The chip select pin disables only the control logic interface, and does not change the operation of the signal matrix. The chip select pin does not power down any of the latches, so any data programmed in the latches is preserved. First Rank Write Enable. Forcing this pin to logic LOW allows the data on pins D[6:0] to be stored in the first rank latch for the output specified by pins A[4:0]. The WE pin must be returned to a logic HIGH state after a write cycle to avoid overwriting the first rank data. UPDATE Input Second Rank Write Enable. Forcing this pin to logic LOW allows the data stored in all 17 first rank latches to be transferred to the second rank latches. The signal connection matrix will be reprogrammed when the second rank data is changed. This is a global pin, transferring all 17 rows of data at once. It is not necessary to program the address pins. It should be noted that after initial power-up of the device, the first rank data is undefined. It may be desirable to preprogram all seventeen outputs before performing the first update cycle. RE Input Second Rank Read-Enable. Forcing this pin to logic LOW enables the output drivers on the bidirectional D[6:0] pins, entering the readback mode of operation. By selecting an output address with the A[4:0] pins and forcing RE to logic LOW, the 7-bit data stored in the second rank latch for that output address will be written to D[6:0] pins. Data should not be written to the D[6:0] pins externally while in readback mode. The RE and WE pins are not exclusive, and may be used at the same time, but data should not be written to the D[6:0] pins from external sources while in readback mode. CS Input Chip-Select. This pin must be forced to logic LOW in order to program or receive data from the logic interface, with the exception of the RESET pin, described below. This pin has no effect on the signal pairs and does not alter any of the stored control data. RESET Input Global Output Disable Pin. Forcing the RESET pin to logic LOW will reset the enable bit, D6, in all 17 second rank latches, regardless of the state of any other pins. This has the effect of immediately disabling the 17 output signal pairs in the All control pins are level-sensitive, not edge-triggered. –16– REV. 0 AD8151 matrix. It is useful to momentarily hold RESET at a logic LOW state when powering up the AD8151 in a system that has multiple output signal pairs connected together. Failure to do this may result in several signal outputs contending after power-up. The reset pin is not gated by the state of the chip-select pin, CS. It should be noted that the RESET pin does not program the first rank, which will contain undefined data after power-up. CONTROL INTERFACE TRANSLATORS The AD8151 control interface has two supply pins, VDD and VSS. The potential between the positive logic supply VDD and the negative logic supply VSS must be at least 3 V and no more than 5 V. Regardless of supply, the logic threshold is approximately 1.6 V above VSS, allowing the interface to be used with most CMOS and TTL logic drivers. In order to maintain signal fidelity at the high data rates supported by the AD8151, the input transmission lines should be terminated as close to the input pins as possible. The preferred input termination structure will depend primarily on the application and the output circuit of the data source. Standard ECL components have open emitter outputs that require pull-down resistors. Three input termination networks suitable for this type of source are shown in Figure 10. The characteristic impedance of the transmission line is shown as ZO. The resistors, R1 and R2, in the Thevenin termination are chosen to synthesize a VTT source with an output resistance of ZO and an open-circuit output voltage equal to VCC – 2 V. The load resistors (RL) in the differential termination scheme are needed to bias the emitter followers of the ECL source. VCC The signal matrix supplies, VCC and VEE, can be set independent of the voltage on VDD and VSS, with the constraints that (VDD–VEE) ≤ 10 V. These constraints will allow operation of the control interface on 3 V or 5 V while the signal matrix is operated on +3.3 V or +5 V PECL, or –3.3 V or –5 V ECL. The AD8151 has 33 pairs of differential voltage-mode inputs. The common-mode input range extends from the positive supply voltage (VCC) down to include standard ECL or PECL input levels (VCC – 2 V). The minimum differential input voltage is 200 mV. Unused inputs may be connected directly to any level within the allowed common-mode input range. A simplified schematic of the input circuit is shown in Figure 9. VCC INxxN INxxP INxxN ZO ZO INxxP ZO INxxP ZO ECL SOURCE R2 R2 VEE VTT = VCC – 2V (a) (b) VCC ZO INxxN ZO 2ZO INxxP ECL SOURCE RL RL VEE (c) Figure 10. AD8151 Input Termination from ECL/PECL Sources: a) Parallel Termination Using VTT Supply, b) Thevenin Equivalent Termination, c) Differential Termination If the AD8151 is driven from a current mode output stage such as another AD8151, the input termination should be chosen to accommodate that type of source, as explained in the following section. High-Speed Data Outputs (OUTyyP, OUTyyN) The AD8151 has 17 pairs of differential current-mode outputs. The output circuit, shown in Figure 11, is an open-collector NPN current switch with resistor-programmable tail current and output compliance extending from the positive supply voltage (VCC) down to standard ECL or PECL output levels (VCC – 2 V). The outputs may be disabled individually to permit outputs from multiple AD8151s to be connected directly. Since the output currents of multiple enabled output stages connected in this way sum, care should be taken to ensure that the output compliance limit is not exceeded at any time; this can be achieved by disabling the active output driver before enabling any inactive driver. VEE Figure 9. Simplified Input Circuit REV. 0 R1 INxxN CIRCUIT DESCRIPTION High-Speed Data Inputs (INxxP, INxxN) VCC – 2V ZO R1 ZO ECL SOURCE The AD8151 is a high-speed 33 × 17 differential crosspoint switch designed for data rates up to 3.2 Gb/s per channel. The AD8151 supports PECL-compatible input and output levels when operated from a 5 V supply (VCC = 5 V, VEE = GND) or ECL-compatible levels when operated from a –5 V supply (VCC = GND, VEE = –5 V). To save power, the AD8151 can run from a +3.3 V supply to interface with low-voltage PECL circuits or a –3.3 V supply to interface with low-voltage ECL circuits. The AD8151 utilizes differential current mode outputs with individual disable control, which facilitates busing together the outputs of multiple AD8151s to assemble larger switch arrays. This feature also reduces system crosstalk and can greatly reduce power dissipation in a large switch array. A single external resistor programs the current for all enabled output stages, allowing for user control over output levels with different output termination schemes and transmission line characteristic impedances. VCC –17– AD8151 VCC VCC RCOM OUTyyP OUTyyN VCC – 2V AD8151 VCOM RL RL OUTyyN OUTyyP AD8151 ZO ZO OUTyyN OUTyyP IOUT DISABLE ZO ZO RL VEE RL VEE Figure 11. Simplified Output Circuit RECEIVER To ensure proper operation, all outputs (including unused output) must be pulled high using external pull-up networks to a level within the output compliance range. If outputs from multiple AD8151s are wired together, a single pull-up network may be used for each output bus. The pull-up network should be chosen to keep the output voltage levels within the output compliance range at all times. Recommended pull-up networks to produce PECL/ECL 100 kΩ and 10 kΩ compatible outputs are shown in Figure 12. Alternatively, a separate supply can be used to provide VCOM; making RCOM and DCOM unnecessary. VCC VCC RCOM AD8151 RL DCOM VCOM RL AD8151 OUTyyN OUTyyN OUTyyP OUTyyP RL VCOM RL Figure 13. Double Termination of AD8151 Outputs In this case, the output levels are: VOH = VCOM – (1/4) IOUTRL VOL = VCOM – (3/4) IOUTRL VSWING = VOH – VOL = (1/2) IOUTRL Output Current Set Pin (REF) A simplified schematic of the reference circuit is shown in Figure 14. A single external resistor connected between the REF pin and VEE determines the output current for all output stages. This feature allows a choice of pull-up networks and transmission line characteristic impedances while still achieving a nominal output swing of 800 mV. At low data rates, substantial power savings can be achieved by using lower output swings and higher load resistances. Figure 12. Output Pull-Up Networks: a) ECL 100 kΩ, b) ECL 10 kΩ AD8151 IOUT/20 VCC The output levels are simply: REF 1.2V VOH = VCOM RSET VOL = VCOM – IOUTRL VEE VSWING = VOH – VOL = IOUTRL Figure 14. Simplified Reference Circuit VCOM = VCC – IOUTRCOM (100 kΩ Mode) The nominal output current is given by the following expression: VCOM = VCC – V (DCOM) (10 kΩ Mode) The common-mode adjustment element (RCOM or DCOM) may be omitted if the input range of the receiver includes the positive supply voltage. The bypass capacitors reduce common-mode perturbations by providing an ac short from the common nodes (VCOM) to ground. When busing together the outputs of multiple AD8151s or when running at high data rates, double termination of its outputs is recommended to mitigate the impact of reflections due to open transmission line stubs and the lumped capacitance of the AD8151 output pins. A possible connection is shown in Figure 13; the bypass capacitors provide an ac short from the common nodes of the termination resistors to ground. To maintain signal fidelity at high data rates, the stubs connecting the output pins to the output transmission lines or load resistors should be as short as possible. 1 .2 V IOUT = 20 RSET The minimum set resistor is RSET,MIN = 960 Ω resulting in IOUT,MAX = 25 mA. The maximum set resistor is RSET,MAX = 4.8 kΩ resulting in IOUT,MIN = 5 mA. Nominal 800 mV differential output swing can be achieved in a 50 Ω load using RSET = 1.5 kΩ (IOUT = 16 mA), or in a doubly-terminated 75 Ω load using RSET = 1.13 kΩ (IOUT = 21.3 mA). To minimize stray capacitance and avoid the pickup of unwanted signals, the external set resistor should be located close to the REF pin. Bypassing the set resistor is not recommended. –18– REV. 0 AD8151 the part is to be ac-coupled, it is not necessary to have the input/ output common mode at the same level as the other system circuits, but it will probably be more convenient to use the same supply rails for all devices. Power Supplies There are several options for the power supply voltages for the AD8151, as there are two separate sections of the chip that require power supplies. These are the control logic and the high-speed data paths. Depending on the system architecture, the voltage levels of these supplies can vary. Logic Supplies The control (programming) logic is CMOS and is designed to interface with any of the various standard single-ended logic families (CMOS or TTL). Its supply voltage pins are VDD (Pin 170, logic positive) and VSS (Pin 152, logic ground). In all cases the logic ground should be connected to the system digital ground. VDD should be supplied at between 3.3 V to 5 V to match the supply voltage of the logic family that is used to drive the logic inputs. VDD should be bypassed to ground with a 0.1 µF ceramic capacitor. The absolute maximum voltage from VDD to VSS is 5.5 V. For PECL operation, VEE will be at ground potential and VCC will be a positive voltage from 3.3 V to 5 V. Thus, the common mode of the inputs and outputs will be at a positive voltage. These can then be dc-coupled to other PECL operated devices. If the data paths are ac-coupled, then the common-mode levels do not matter, see Figure 16. +3.3V TO +5V VDD The data path supplies have more options for their voltage levels. The choices here will affect several other areas, like power dissipation, bypassing, and common mode levels of the inputs and outputs. The more positive voltage supply for the data paths is VCC (Pins 41, 98, 149 and 171). The more negative supply is VEE, which appears on many pins that will not be listed here. The maximum allowable voltage across these supplies is 5.5 V. GND 0.1F VDD VCC AD8151 CONTROL LOGIC +3.3V TO +5V DATA PATHS VSS VEE GND GND Figure 16. Power Supplies and Bypassing for PECL Operation POWER DISSIPATION For analysis, the power dissipation of the AD8151 can be divided into three separate parts. These are the control logic, the data path circuits and the (ECL or PECL) outputs, which are part of the data path circuits, but can be dealt with separately. The first of these, the control logic, is CMOS technology and does not dissipate a significant amount of power. This power will, of course, be greater when the logic supply is 5 V rather than 3 V, but overall it is not a significant amount of power and can be ignored for thermal analysis. VCC AD8151 VDD CONTROL LOGIC VCC ROUT AD8151 DATA PATHS IOUT DATA PATHS CONTROL LOGIC VSS VEE I, DATA PATH LOGIC 0.1F (ONE FOR EVERY TWO VEE PINS) GND VSS –3.3V TO –5V Figure 15. Power Supplies and Bypassing for ECL Operation If the data paths are to be dc-coupled to other ECL logic devices that run with ground as the most positive supply and a negative voltage for VEE, then this is the proper way to run. However, if REV. 0 0.1F (ONE FOR EACH VCC PIN, 4 REQUIRED) 0.1F Data Path Supplies The first choice in the data path power supplies is to decide whether to run the device as ECL (Emitter-Coupled Logic) or PECL (Positive ECL). For ECL operation, VCC will be at ground potential, while VEE will be at a negative supply between –3.3 V to –5 V. This will make the common-mode voltage of the inputs and outputs at a negative voltage, see Figure 15. +3.3V TO +5V GND VOUT LOW – VEE VEE GND Figure 17. Major Power Consumption Paths The data path circuits operate between the supplies VCC and VEE. As described in the power supply section, this voltage can range from 3.3 V to 5 V. The current consumed by this section will be constant, so operating at a lower voltage can save about 35 percent in power dissipation. –19– AD8151 The power dissipated in the data path outputs is affected by several factors. The first is whether the outputs are enabled or disabled. The worst case occurs when all of the outputs are enabled. the pin leads can provide an even lower thermal resistive path. If possible to use, 2 oz. copper foil will provide better heat removal than 1 oz. The current consumed by the data path logic can be approximated by: The AD8151 package has a specified thermal impedance θJA of 30°C/W. This is the worst case, still-air value that can be expected when the circuit board does not significantly enhance the heat removal from the package. By using the concept described above or by using forced-air circulation, the thermal impedance can be lowered. ICC = 35 mA + [4.5 mA + (IOUT/20 mA × 3 mA)] × (# of outputs enabled) This says that there will always be a minimum of 35 mA flowing. ICC will increase by a factor that is proportional to both the number of enabled outputs and the programmed output current. The power dissipated in this circuit section will simply be the voltage of this section (VCC – VEE) times the current. For a worst case, assume that VCC – VEE is 5.0 V, all outputs are enabled and the programmed output current is 25 mA. The power dissipated by the data path logic will be: P = 5.0 V {35 mA + [4.5 mA + (25 mA/20 mA × 3 mA)] × 17} = 876 mW APPLICATIONS AD8151 INPUT AND OUTPUT BUSING The power dissipated by the output current depends on several factors. These are the programmed output current, the voltage drop from a logic low output to VEE and the number of enabled outputs. A simplifying assumption is that one of each (enabled) differential output pair will be low and draw the full output current (and dissipate most of the power for that output), while the complementary output of the pair will be high and draw insignificant current. Thus, its power dissipation of the high output can be ignored and the output power dissipation for each output can be assumed to occur in a single static low output that sinks the full output-programmed current. The voltage across which this current flows can also vary, depending on the output circuit design and the supplies that are used for the data path circuitry. In general, however, there will be a voltage difference between a logic low signal and VEE. This is the drop across which the output current flows. For a worst case, this voltage can be as high as 3.5 V. Thus, for all outputs enabled and the programmed output current set to 25 mA, the power dissipated by the outputs: Although the AD8151 is a digital part, in any application that runs at high speed, analog design details will have to be given very careful consideration. At high data rates, the design of the signal channels will have a strong influence on the data integrity and its associated jitter and ultimately bit error rate (BER). While it might be considered very helpful to have a suggested circuit board layout for any particular system configuration, this is not something that can be practically realized. Systems come in all shapes, sizes, speeds, performance criteria and cost constraints. Therefore, some general design guidelines will be presented that can be used for all systems and judiciously modified where appropriate. High-speed signals travel best, i.e. maintain their integrity, when they are carried by a uniform transmission line that is properly terminated at either end. Any abrupt mismatches in impedance or improper termination will create reflections that will add to or subtract from parts of the desired signal. Small amounts of this effect are unavoidable, but too much will distort the signal to the point that the channel BER will increase. It is difficult to fully quantify these effects, because they are influenced by many factors in the overall system design. P = 3.5 V (25 mA) × 17 = 1.49 W HEAT SINKING Depending on several factors in its operation, the AD8151 can dissipate upwards of 2 W or more. The part is designed to operate without the need for an explicit external heatsink. However, the package design offers enhanced heat removal via some of the package pins to the PC board traces. The VEE pins on the input sides of the package (Pins 1 to 46 and Pins 93 to 138) have “finger” extensions inside the package that connect to the “paddle” upon which the IC chip is mounted. These pins provide a lower thermal resistance from the IC to the VEE pins than other pins that just have a bond wire. As a result these pins can be used to enhance the heat removal process from the IC to the circuit board and ultimately to the ambient. The VEE pins described above should be connected to a large area of circuit board trace material in order to take most advantage their lower thermal resistance. If there is a large area available on an inner layer that is at VEE potential, then vias can be provided from the package pin traces to this layer. There should be no thermal-relief pattern when connecting the vias to the inner layers for these VEE pins. Additional vias in parallel and close to For an extreme worst case analysis, the junction rise above the ambient can be calculated assuming 2 W of power dissipation and θJA of 30°C/W to yield a 60°C rise above the ambient. There are many techniques described above that can mitigate this situation. Most actual circuits will not result in this high a rise of the junction temperature above the ambient. A constant-impedance transmission line is characterized by having a uniform cross-section profile over its entire length. In particular, there should be no “stubs,” which are branches that intersect the main run of the transmission line. These can have an electrical “appearance” that is approximated by a lumped element, such as a capacitor, or if long enough, as another transmission line. To the extent that stubs are unavoidable in a design, their effect can be minimized by making them as short as possible and as high an impedance as possible. Figure 13 shows a differential transmission line that connects two differential outputs from AD8151s to a generic receiver. A more generalized system can have more outputs bused, and more receivers on the same bus, but all the same concepts apply. The inputs of the AD8151 can also be considered as a receiver. The transmission lines that bus all of the devices together are shown with terminations at each end. The individual outputs of the AD8151 are stubs that intersect the main transmission line. Ideally, their current-source outputs would be infinite impedance, and they would have no effect on signals that propagate along the transmission line. In reality, each –20– REV. 0 AD8151 external pin of the AD8151 projects into the package, and has a bond wire connected to the chip inside. On-chip wiring then connects to the collectors of the output transistors and to ESD protection diodes. Unlike some other high-speed digital components, the AD8151 does not have on-chip terminations. While this location would be closer to the actual end of the transmission line for some architectures, this concept can limit system design options. In particular, it is not possible to bus more than two inputs or outputs on the same transmission line and it is also not possible to change the value of these terminations to use for different impedance transmission lines. The AD8151, with the added ability to disable its outputs, is much more versatile in these types of architectures. If the external traces are kept to a bare minimum, then the output will present a mostly lumped capacitive load of about 2 pF. A single stub of 2 pF will not seriously adversely affect signal integrity for most transmission lines, but the more of these stubs, the more adverse their influence will be. One way to mitigate this effect is to locally reduce the capacitance of the main transmission line near the point of stub intersection. Some practical means for doing this are to narrow the PC board traces in the region of the stub and/or to remove some of the ground plane(s) near this intersection. The effect of these techniques will locally lower the capacitance of the main transmission line at these points, while the added capacitance of the AD8151 outputs will “compensate” for this reduction in capacitance. The overall intent is to create as uniform a transmission line as possible. Operating in PECL mode requires VCC to be at a positive voltage, while VEE is at ground. Since this would make the shells of the I/O connectors at a positive voltage, it can cause problems when directly connecting to test equipment. Some equipment, such as battery-operated oscilloscopes, can be “floated” from ground, but care should be taken with line-powered equipment to avoid creating a dangerous situation. Refer to the manual of the test equipment that is being used. The voltage difference from VCC to VEE can range from 3 V to 5 V. Power savings can be realized by operating at a lower voltage without any compromise in performance. A separate connection is provided for VTT, the termination potential of the outputs. This can be at a voltage as high as VCC, but power savings can be realized if VTT is at a voltage that is somewhat lower. Please consult elsewhere in the data sheet for the specification for the limits of the VTT supply. As a practical matter, current on the evaluation board will flow from the VTT supply, through the termination resistors, into the multiple outputs of the AD8151, and on to the VEE supply. When running in ECL mode, VTT will want to be at a negative supply. Most power supplies will not allow their ground connection to VCC and then the negative supply to VTT. This will require them to source current from their negative supply, which wants to flow to the more-negative VEE. This current will not then return to the ground terminal of the VTT supply. Thus, VTT should be referenced to VEE when running in ECL mode or a true bipolar supply should be used. In selecting the location of the termination resistors it is important to keep in mind that, as their name implies, they should be placed at either end of the line. There should be no or minimal projection of the transmission line beyond the point where the termination resistors connect to it. The digital supply is provided to the AD8151 by the VDD and VSS pins. VSS should always be at ground potential to make it compatible with standard CMOS or TTL logic. VDD can range from 3 V to 5 V, and should be matched to the supply voltage of the logic used to control the AD8151. However, since PCs use 5 V logic on their parallel port, VDD should be at 5 V when using a PC to program the AD8151. EVALUATION BOARD Bypassing An evaluation board has been designed and is available to rapidly test the main features of the AD8151. This board lets the user analyze the analog performance of the AD8151 channels and easily control the configuration of the board by a standard PC. The board has limited numbers of differential input/output pairs. Each differential pair of microstrip is connected to either top-mount or side-launch SMA connectors. The top-mount SMA connectors are drilled and stubbed for superior performance. The FR4 type board contains a total of nine outputs (all even numbered outputs) and 20 inputs (numbers 0, 2, 4, 6, 8, 10, 12, 13, 14, 15, 16, 17, 18, 20, 22, 24, 26, 28, 30, 32). It is important to note that the shells of the SMA connectors are attached to VCC. This makes only ECL or negative level swings possible during testing. Power Supplies The AD8151 is designed to work with standard ECL logic levels. This means that VCC is at ground and VEE is at a negative supply. The shells of the I/O SMA connectors are at VCC potential. Thus, when operating in the standard ECL configuration, test equipment can be directly connected to the board, as the test equipment will have its connector “shells” at ground potential also. REV. 0 Most of the board’s bypass capacitors are opposite the DUT on the solder side, connected between VCC and VEE. This is where they will be most effective. These capacitors are 0.01 µF ceramic chip capacitors for low inductance. There are additional higher value capacitors elsewhere on the board for bypassing at lower frequencies. The location of these is not as critical. Input and Output Considerations Each input contains a 100 Ω differential termination. Although the differential termination eases board layout due to its compact nature, it can cause problems with the driving generator. A typical pulse or pattern generator wants to see 50 Ω to ground (or to –2 V in some cases). High speed probing of the input showed if this type of termination is not present then input amplitudes could be slightly off. Even more affected can be the dc input levels. Depending on the generator used, these levels can be off as much as 800 mV in either direction. A correction for this problem is to attach a 6 dB attenuator to each P and N input. Because the AD8151 has a large common-mode voltage range on its input stage, it will not be significantly affected by dc level errors. –21– AD8151 On this evaluation board all unused inputs are tied to VCC (GND). All outputs, whether brought out to connectors or not, are tied to VTT through a 49.9 Ω resistor. The AD8151 device is on the component side of the board, while input terminations and output back terminations are on the circuit side. The input signals from the circuit side transit through via holes to the DUT’s pads. The component-side output signals connect to via holes and to circuit-side 49.9 Ω termination resistors. Board Construction For this board FR4 material was chosen over more exotic board materials. Tests showed exotic materials to be unnecessary. This is a 4-layer board. Power is bused on both external and internal layers. Test structures showed microstrip performance to be unaffected by the dc bias levels on the plane beneath it. The manufacturing process should produce a controlledimpedance board. The board stack consists of a 5-mil-thick layer between external and internal layers. This allows the use of an 8-mil-wide microstrip trace running from SMA connector to the DUT’s pads. The narrow trace avoids the need to neck down the trace width as DUT’s pads are approached and it helps to control the microstrip trace impedance. The thin 5-mil dielectric also helps to control crosstalk by way of confining the electromagnetic fields more between the trace and the plane below. Configuration Programming The board is configurable by one of two methods. For ease of use, custom software is provided that controls the AD8151 programming via the parallel port of a PC. This requires a usersupplied standard printer cable that has a DB-25 connector at one end (parallel- or printer-port interface) and a Centronixtype connector at the other that connects to P2 of the AD8151 evaluation board. The programming with this scheme is done in a serial fashion, so it is not the fastest way to configure the AD8151 matrix. However, the user interface makes it very convenient to use this programming method. If a high-speed programming interface is desired, the AD8151 address and data buses are directly available on P3. The source of the program signals can be a piece of test equipment, like the Tektronix HFS-9000 digital test generator, or some other usersupplied hardware that generates programming signals. When using the PC interface, the jumper at W1 should be installed and no connections should be made to P3. When using the P3 interface, no jumper is installed at W1. There are locations for termination resistors for the address and data signals if these are necessary. Software Installation The software to operate the AD8151 is provided on two 3.5" floppy disks. The software is installed by inserting Disk 1 into the floppy drive of a PC and running the “setup.exe” program. This will routinely install the software and prompt the user when to change to Disk 2. The setup program will also prompt the user to select the directory for the program. After running the software, the user will be prompted to identify which (of three) software driver is used with the PC’s parallel port. The default is LPT1, which is most commonly used. However, some laptops commonly use the PRN driver. It is also possible that some systems are configured with the LPT2 driver. If it is not known which driver is used, it is best to select LPT1 and proceed to the next screen. This will show a full array of “buttons” that allows the connection of any input to output of the AD8151. All of the outputs should be in the output “OFF” state right after the program starts running. Any of the active buttons can be selected with a mouse click, which will send out one burst of programming data. After this, the PC keyboard’s left or right arrow keyboard key can be held down to generate a steady stream of programming signals out of the parallel port. The CLOCK test point on the AD8151 evaluation board can be monitored with an oscilloscope for any activity (user-supplied printer cable must be connected). If there is a square-wave present, the proper software driver is selected for the PC’s parallel port. If there is no signal present, another driver should be tried by selecting the Parallel Port menu item under the “File” pulldown menu selection just under the title bar. Select a different software driver and carry out the above test until signal activity is present at the CLOCK test point. Software Operation Any button can be clicked in the matrix to program the input to output connection. This will send the proper programming sequence out the PC parallel port. Since only one input can be programmed to a given output at one time, clicking a button in a horizontal row will cancel the other selection that is already selected in that row. However, any number of outputs can share the same input. A shortcut for programming all outputs to the same input is to use the broadcast feature. After clicking on the Broadcast Connection button, a screen will appear that will prompt for the user to select which input should be connected to all outputs. The user should type in an integer from 0 to 32 and then click on OK. This will send out the proper program data and return to the main screen with a full column of buttons selected under the chosen input. The Off column can be used to disable to whichever output one chooses. To disable all outputs, the Global Reset button can be clicked. This will select the full column of OFF buttons. Two scratch-pad memories (Memory 1 and Memory 2) are provided to conveniently save a particular configuration. However, these registers are erased when the program is terminated. For long-term storage of configurations, the disk-storage memory should be used. The Save and Load selections can be accessed from the “File” pull-down menu under the title bar. –22– REV. 0 AD8151 AD8151 Figure 18. Evaluation Board Controller REV. 0 –23– AD8151 Figure 19. Component Side –24– REV. 0 AD8151 Figure 20. Circuit Side REV. 0 –25– AD8151 Figure 21. Silkscreen Top –26– REV. 0 AD8151 Figure 22. Soldermask Top REV. 0 –27– AD8151 Figure 23. Silkscreen Bottom –28– REV. 0 AD8151 Figure 24. Soldermask Bottom REV. 0 –29– AD8151 Figure 25. INT1 (VEE) –30– REV. 0 AD8151 Figure 26. INT2 (VCC) REV. 0 –31– AD8151 VEE VCC VEE VCC C12 0.01F C6 0.01F C8 0.01F VEE VEE VCC C10 0.01F C14 0.01F 143 144 IN14N IN14P IN15N IN15P 145 146 147 148 149 150 152 151 153 154 155 156 157 158 159 160 161 163 162 164 165 166 167 168 IN13N IN13P VEE VCC VDD RESET CS RE WE UPDATE A0 A1 A2 A3 A4 D0 D1 D2 D3 D4 D5 D6 169 170 171 IN16N IN16P 172 173 174 175 IN17N IN17P 176 177 IN18N IN18P 178 179 180 181 IN19N IN19P 182 184 183 1 2 VDD VSS C13 0.01F VCC VEE C30 0.01F 138 137 136 135 134 133 132 131 130 129 128 127 126 125 124 123 122 121 PIN 1 IDENTIFIER 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 120 119 118 117 116 AD8151 184L LQFP TOP VIEW (Not to Scale) 115 114 113 112 111 110 109 108 107 106 105 104 103 102 101 100 40 41 42 43 44 45 46 99 98 VCC VEE OUT00P OUT00N VEE VEE C60 0.01F VEE 92 91 90 89 87 88 86 85 84 83 82 81 80 79 78 77 76 75 74 73 72 71 70 69 67 68 66 65 64 62 63 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 97 96 95 94 93 VEE IN12N IN12P VEE IN11N IN11P VEE IN10N IN10P VEE IN09N IN09P VEE IN08N IN08P VEE IN07N IN07P VEE IN06N IN06P VEE IN05N IN05P VEE IN04N IN04P VEE IN03N IN03P VEE IN02N IN02P VEE IN01N IN01P VEE IN00N IN00P VEE VEE OUT15N OUT15P VEE OUT14N OUT14P VEE OUT13N OUT13P VEE OUT12N OUT12P VEE OUT11N OUT11P VEE OUT10N OUT10P VEE OUT09N OUT09P VEE OUT08N OUT08P VEE OUT07N OUT07P VEE OUT06N OUT06P VEE OUT05N OUT05P VEE OUT04N OUT04P VEE OUT03N OUT03P VEE OUT02N OUT02P VEE OUT01N OUT01P VEE C31 VEE 0.01F IN20P VCC IN20N VEE IN21P IN21N VEE IN22P VCC IN22N C32 VEE 0.01F IN23P IN23N VEE IN24P IN24N VEE IN25P IN25N VEE IN26P IN26N VEE IN27P IN27N VEE IN28P IN28N VEE IN29P IN29N VEE IN30P IN30N VEE IN31P IN31N VEE C11 IN32P 0.01F IN32N VCC VEE VEE VEE OUT16N VCC C15 OUT16P VEE 0.01F VEE VEE VCC VCC VEE C4 0.01F C29 0.01F C9 0.01F R203 1.5k 140 VCC VEE VEE VCC 139 C7 0.01F 141 C5 0.01F 142 VCC VEE VEE VCC Figure 27. Bypassing Schematic –32– REV. 0 AD8151 VCC R19 1.65k VCC IN00P P4 R20 105 P5 IN00N R21 1.65k R40 1.65k VCC IN06P VCC IN12P P28 P16 R39 105 P17 IN06N R38 1.65k VEE R58 1.65k VCC IN18P R56 1.65k IN12N R90 105 P41 VCC IN24P IN24N R92 1.65k VEE R116 1.65k IN30P OUT08P R160 49.9 R117 105 P65 R118 1.65k VEE OUT08N R162 49.9 P30 VEE OUT09P R28 1.65k P8 VCC IN02P R27 105 P9 R44 1.65k R165 49.9 P20 R45 105 IN02N R46 1.65k VEE IN08N R62 1.65k P32 R63 105 R85 1.65k P44 VCC IN20P R175 49.9 IN20N IN26P R99 105 OUT11P R112 1.65k P68 IN26N R125 49.9 VTT OUT01N R127 49.9 OUT02P R130 49.9 P99 R111 105 VTT OUT02N P82 R132 49.9 VTT OUT11 N R172 49.9 OUT12P R185 49.9 VTT OUT03N R133 49.9 VEE VEE OUT04P R140 49.9 IN32N P79 VTT OUT12N R183 49.9 IN15P OUT13P OUT04N P78 R180 49.9 IN15N OUT13N P95 VTT R142 49.9 P94 R145 OUT05P 49.9 VTT VTT R67 1.65k P98 R135 OUT03P 49.9 R170 49.9 IN32P R110 1.65k R66 105 P35 P102 P69 R100 1.65k VEE R173 49.9 VCC P34 OUT01P VCC P57 R83 1.65k VEE R98 1.65k P56 R84 105 P45 IN14N R65 1.65k R122 49.9 VTT VCC IN14P R64 1.65k VEE OUT10P OUT10N P33 P21 R26 1.65k OUT09N R163 49.9 IN13N VCC IN08P OUT00N P86 P83 VEE VCC VTT IN13P R61 1.65k R121 49.9 VTT R60 105 P31 P103 OUT00P IN30N VCC R59 1.65k P87 VTT P64 R93 105 P53 IN18N R91 1.65k VEE R94 1.65k P52 P40 R57 105 P29 VEE R89 1.65k R182 49.9 OUT05N R143 49.9 OUT06P R150 49.9 VEE VCC R34 1.65k P12 VCC IN04P R33 105 P13 R32 1.65k VEE IN04N R50 1.65k P24 VCC IN10P R51 105 P25 R52 1.65k IN10N R68 1.65k P36 IN16P R69 105 P37 R79 1.65k P48 IN16N VEE VCC IN22P OUT14P R104 1.65k P60 R78 105 P49 R70 1.65k VEE VCC R105 105 P38 OUT14N IN22N VEE R106 1.65k IN28N OUT15P IN01, IN03, IN05, IN07, IN09, IN11, IN19, IN21, IN23, IN25, IN27, IN29, IN31 OUT15N R192 49.9 OUT16P R200 49.9 N OUT16N R198 49.9 OUT07N –33– R153 49.9 C16 0.01F P71 VCC VTT C82 0.01F VCC VTT P70 C83 0.01F VTT Figure 28. Evaluation Board Input/Output Schematic P90 VTT VTT VEE REV. 0 R152 49.9 R155 OUT07P 49.9 P P39 IN17N OUT06N P74 R190 49.9 VEE R72 105 R73 1.65k VTT VTT VCC IN17P R193 49.9 P61 R77 1.65k P91 P75 VTT IN28P VCC R71 1.65k R195 49.9 VCC AD8151 CLK A1 1 CLK P2 6 74HC14 DATA 3 DATA P2 5 A1 4 74HC14 VSS P2 25 2 5 1 A1 2 6 3 74HC14 4 5 VSS 6 7 VDD 8 9 10 VSS VCC OUT_EN 20 19 1 VDD 2 Q0 18 Q1 17 Q2 D2 16 Q3 D3 A2 15 D4 74HC74 Q4 14 Q5 D5 13 Q6 D6 12 Q7 D7 11 CLK GND D0 D1 3 OUT_EN VCC Q0 D0 Q1 D1 4 Q2 D2 5 D3 Q3 A3 6 D4 74HC74 Q4 7 D5 Q5 8 D6 Q6 9 D7 Q7 10 GND CLK VDD VSS 20 19 A1 9 VDD VDD 8 74HC14 A1 11 10 18 17 74HC14 A1 12 16 15 13 14 12 74HC14 A4 9 11 10 13 8 74HC132 A4 12 13 R7 49.0 VSS VSS VSS 1 A4 2 74HC132 WRITE RESET READ D0 A4 A3 A2 A1 A0 D6 D5 D4 D3 D2 D1 UPDATE CHIP_SELECT VDD P3 13 P3 7 P3 11 P3 27 P3 25 P3 23 P3 21 P3 19 P3 17 P3 39 P3 37 P3 35 P3 33 P3 31 P3 29 P3 15 P3 9 P3 5 VSS P3 14 P3 8 P3 12 P3 28 P3 26 P3 24 P3 22 P3 20 P3 18 P3 40 P3 38 P3 36 P3 34 P3 32 P3 30 P3 16 P3 10 P3 6 VSS 164A0 VSS VSS P2 7 P2 3 P2 8 P2 4 P2 2 VSS 163A1 3 4 5 VSS A4 153D6 R13 49.0 154D5 R14 49.0 162A2 R11 49.0 W1 READ RESET WRITE UPDATE CHIP_SELECT VSS R10 49.0 VSS VDD 161A3 R9 49.0 VSS R1 20k VSS 74HC132 R12 49.0 160A4 R8 49.0 155D4 R15 49.0 156D3 R16 49.0 157D2 R17 49.0 158D1 R18 49.0 6 VSS 11 159D0 74HC132 TP5 TP6 TP4 TP20 TP9 TP10 TP11 TP12 TP13 TP14 TP15 TP16 TP17 TP18 TP19 TP7 TP8 VDD VSS VSS VSS VSS VSS VSS R2 49.0 R3 49.0 R4 49.0 R5 49.0 R6 49.0 CHIP_SELECT 168 UPDATE 165 VTT P1 6 C3 + 10F WRITE 166 VCC P1 1 P1 2 RESET 169 VEE READ 167 P1 3 P1 4 VDD P1 7 VSS P1 5 + C1 10F + C2 10F VTT VTT A1, 4 PIN 14 IS TIED TO VDD. A1, 4 PIN 7 IS TIED TO VSS. VCC VCC VEE VEE VDD C86 0.1F VDD C87 0.1F VDD C88 0.1F VDD C89 0.1F VDD VSS VSS VSS VSS VSS P104 P105 Figure 29. Evaluation Board Logic Controls –34– REV. 0 AD8151 OUTLINE DIMENSIONS Dimensions shown in mm and (inches). 184-Lead Plastic LQFP (ST-184) 1.60 (0.063) MAX 0.75 (0.030) 0.60 (0.024) 0.45 (0.018) SEATING PLANE 22.00 (0.866) BSC SQ 20.00 (0.787) BSC SQ 186 1 139 138 PIN 1 TOP VIEW (PINS DOWN) 0.08 (0.003) 0.15 (0.006) 0.05 (0.002) 1.45 (0.057) 1.40 (0.053) 1.35 (0.048) 46 47 93 92 0.40 (0.016) BSC 0.23 (0.009) 0.18 (0.007) 0.13 (0.005) CONTROLLING DIMENSIONS ARE IN MILLIMETERS REV. 0 –35– –36– PRINTED IN U.S.A. C02169–1.5–4/01(0)