A Cirrus Logic Company CS61535A T1/E71 Line Interface Features Provides Analog PCM Line Interface for T1 and E1 Applications Provides Line Driver, and Data and Clock Recovery Functions Transmit Side Jitter Attenuation Starting at 6 Hz, with > 300 UI of Jitter Tolerance @ Low Power Consumption (typically 175 mW) B8ZS/HDB3/AMI Encoders/Decoders @ 14 dB of Transmitter Return Loss Compatible with SONET, M13 , CCITT G.742, and Other Asynchronous Muxes General Description The CS61535A combines the complete analog transmit and receive line interface for T1 or E1 applications in a low power, 28-pin device operating from a +5V supply. The device features a transmitter jitter attenuator mak- ing it ideal for use in asynchronous multiplexor systems with gapped transmit clocks. The CS61535A provides a matched, constant impedance output stage to insure signal quality on mismatched, poorly terminated lines. Both ICs use a digital Delay-Locked-Loop clock and data recovery circuit which is continuously calibrated from a crystal reference to provide excellent stability and jitter tolerance. Applications Interfacing network transmission equipment such as SONET multiplexor and M13 to a DSX-1 cross connect. Interfacing customer premises equipment to a CSU. Interfacing to E1 links. Ordering Information CS61535A-IP1 28 Pin Plastic DIP CS61535A-IL1 28 Pin PLCC (j-leads) [ ] = Pin Function in Extended Hardware Mode ()= | ) (CLKE) (INT) (SDI) (SDO) Pin Function in Host Mode XTALIN XTALOUT MODE TAOS LENO LEN1 LEN2 TGND TV+ ? a 0 1s 128 123 124 [25 } 4 | 5 TCLK _ |_| | 13, TTIP JITTER CONTROL PULSE |_ rH ATTENUATOR |_| SHAPER TPOS TRING [TDATA] AMI | LINE DRIVER TNEG B8ZS | LINE RECEIVER 19 CODE] HDB3 | |. CLOCK & ORTIP CODER DATA __ P RPOS RECOVERY ORRING Malia, LOOP OMTIP BACK SIGNAL [RCODE] [BPV] QUALITY DRIVER OMRING MONITOR MONITOR [PCS] DPM 26 27 { 12 24 22 [AIS] RLOOP LLOOP ACLKI LOS RV+ RGND (CS) (SCLK) Crystal Semiconductor Corporation MAY 96 P.O. Box 17847, Austin, TX 78760 Copyright Crystal Semiconducior Corporation 1996 DS40F2 (512) 445-7222 FAX: (512) 445-7581 (All Righis Reserved) 14D mn EH EGD aD a lH manawa nn CS61535A ABSOLUTE MAXIMUM RATINGS Parameter Symbol Min Max Units DC Supply (referenced to RGND, TG@ND=0V) RV+ - 6.0 Vv TV+ - (RV+) + 0.3 V Input Voltage, Any Pin (Note 1) Vin RGND-O.3 (RV+) + 0.3 Vv Input Current, Any Pin (Note 2) lin -10 10 mA Ambient Operating Temperature Ta -40 85 C Storage Temperature Tstg -65 150 C WARNING: Operations at or beyond these limits may result in permanent damage to the device. Normal operation is not guaranteed at these extremes. Notes: 1. Excluding RTIP, RRING, which must stay within -6V to (RV+) + 0.3V. 2. Transient currents of up to 100 mA will not cause SCR latch-up. Also TTIP, TRING, TV+ and TGND can withstand a continuous current of 100 mA. RECOMMENDED OPERATING CONDITIONS Parameter Symbol Min Typ Max Units DC Supply (Note 3) | RV+, TV+| 4.75 5.0 5.25 V Ambient Operating Temperature TA -40 25 85 C Power Consumption (Notes 4, 5) Pc - 290 350 mw Power Consumption (Notes 4, 6) Pc - 175 - mW Notes: 3. TV+ must not exceed RV+ by more than 0.3V. 4. Power consumption while driving line load over operating temperature range. Includes IC and load. Digital input levels are within 10% of the supply rails and digital outputs are driving a 50 pF load. 5. Assumes 100% ones density and maximum line length at 5.25V. 6. Assumes 50% ones density and 300ft. line length at 5.0V. 2 DS40F2DIGITAL CHARACTERISTICS (ta = CS61535A -40C to 85C; TV+, RV+ = 5.0V +5%; GND = 0V) Parameter Symbol Min Typ Max Units High-Level Input Voltage Pins 1-4, 17, 18, 23-28 (Notes 7, 8,9)| Vi 2.0 - - Vv Low-Level Input Voltage Pins 1-4, 17, 18, 23-28 (Notes 7, 8,9)) VIL - - 0.8 Vv High-Level Output Voltage (IOUT = -40 WA) Pins 6-8, 11, 12, 25 (Notes 7, 8,10)| Vou 4.0 - - Vv Low-Level Output Voltage (IOUT = 1.6 mA) Pins 6-8, 11, 12, 23, 25 (Notes 7, 8,10)| VoL - - 0.4 Vv Input Leakage Current (Except Pin 5) - - +10 LA Low-Level Input Voltage, Pin 5 VIL - - 0.2 Vv High-Level Input Voltage, Pin 5 Vi |(RV+) - 0.2 - - Vv Mid-Level Input Voltage, Pin 5 (Note 11)| Vim 2.3 - 2.7 Vv Notes: 7. This specification guarantees TTL compatibility (VoH = 2.4V @ lout = -40uA). 8. In Host Mode, pin 23 is an open drain output and pin 25 is a tristate output. 9. Pins 17 and 18 of the CS61535A are digital inputs in the Extended Hardware Mode. 10. Output drivers will drive CMOS logic levels into a CMOS load. 11. As an alternative to supplying a 2.3-to-2.7V input, this pin may be left floating. ANALOG SPECIFICATIONS (ta = -40C to 85C; TV+, RV+ = 5.0V +5%; GND = 0V) Parameter | Min Typ | Max | Units Jitter Attenuator Jitter Attenuation Curve Corner Frequency (Note 12) - 6 - Hz T1 Jitter Attenuation in Remote Loopback (Note 13) Jitter Freq. [Hz] Amplitude [Ulpp] 10 10 3.0 6.0 - dB 100 10 20 30 - dB 500 10 35 35 - dB 1k 5 40 50 - dB 10k, 40k 0.3 40 50 - dB E1 Jitter Attenuation in Remote Loopback (Note 14) Jitter Freq. [Hz] Amplitude [Ulpp] 10 1.5 3.0 6.0 - dB 100 1.5 20 32 - dB 400 1.5 30 43 - dB 1k 1.5 35 50 - dB 10k, 100k 0.2 35 50 - dB Attenuator Input Jitter Tolerance (Note 15) 12 23 - Ul Notes: 12. Not production tested. Parameters guaranteed by design and characterization. 13. Attenuation measured at the demodulator output of an HP3785B with input jitter equal to 3/4 of measured jitter tolerance using a measurement bandwidth of 1 Hz (10 1kHz) centered around the jitter frequency. With a 2'5_4 PRBS data pattern. Crystal must meet specifcations in CXT6176/8192 datasheet. 14. Jitter measured at the demodulator output of an HP3785A using a measurement bandwidth not to exceed 20 Hz centered around the jitter frequency. With a 2'5_1 PRBS data pattern. Crystal must meet specifications in CXT6176/8192 datasheet. 15. Output jitter increases significantly when attenuator input jitter tolerance is exceeded. DS40F2 3ANALOG SPECIFICATIONS (1a - CS61535A -40C to 85C; TV+, RV+ = 5.0V +5%; GND = 0V) Parameter | Min Typ Max | Units Transmitter AMI Output Pulse Amplitudes (Note 16) EF1, 750 (Note 17) 2.14 2.37 2.6 Vv E1, 120 (Note 18) 27 3.0 3.3 V T1, FCC Part 68 (Note 19) 27 3.0 3.3 V T1, DSX-1 (Note 20) 24 3.0 3.6 V E1 Zero (space) level (LEN2/1/0 = 0/0/0) 75Q application (Note 17) -0.237 - 0.237 V 1200 application (Note 18) -0.3 - 0.3 V Recommended Output Load at TTIP and TRING - 15 - 9 Jitter Added During Remote Loopback (Note 21) 10Hz - 8kHz - 0.005 0.02 Ul 8kHz - 40kHz - 0.008 0.025 Ul 10Hz - 40kHz - 0.010 0.025 Ul Broad Band - 0.015 0.05 Ul Power in 2kHz band about 772kHz (Notes 12, 16) 12.6 15 17.9 dBm Power in 2kHz band about 1.544MHz (Notes 12, 16) -29 -38 - dB (referenced to power in 2kHz band at 772kHz) Positive to Negative Pulse Imbalance (Notes 12, 16) T1, DSX-1 - 0.2 0.5 dB E1 amplitude at center of pulse -5 - 5 % E1 pulse width at 50% of nominal amplitude -5 - 5 % Transmitter Return Loss (Notes 12, 16, 22) 51 kHz to 102 kHz 8 - - dB 102 kHz to 2.048 MHz 14 - - dB 2.048 MHz to 3.072 MHz 10 - - dB Transmitter Short Circuit Current (Notes 12, 23) - - 50 mA RMS Notes: 16. Using a 0.47 uF capacitor in series with the primary of a transformer recommended in the Applications Section. 17. Amplitude measured at the transformer (CS61535A-1:1 or 1:1.26) output across a 75 load for line length setting LEN2/1/0 = 0/0/0. 18. Amplitude measured at the transformer (CS61535A-1:1.26) output across a 120 load for line length setting LEN2/1/0 = 0/0/0. 19. Amplitude measured at the transformer (CS61535A-1:1.15) output across a 100 load for line length setting LEN2/1/0 = 0/1/0. 20. Amplitude measured across a 100 load at the DSX-1 cross-connect for line length settings LEN2/1/0 = 0/1/1, 1/0/0, 1/0/1, 1/1/0 and 1/1/14 after the length of #22 AWG ABAM equivalent cable specified in Table 3. The CS61535A requires a 1:1.15 transformer. 21. Input signal to RTIP/RRING is jitter free. Values will reduce slightly if jitter free clock is input to TCLK. 22. Return loss = 20 logio ABS((z1 +zo)/(z1-zo)) where z1 = impedance of the transmitter, and Zo = impedance of line load. Measured with a repeating 1010 data pattern with LEN2/1/0 = 0/0/0 and a 1:1 transformer terminated with a 75Q load, or a 1:1.26 transformer terminated with a 1200 load. 23. Measured broadband through a 0.5 resistor across the secondary of a 1:1.26 transformer during the transmission of an all ones data pattern for LEN2/1/0 = 0/0/0. DS40F24D mn EH EGD aD a lH manawa nn CS61535A ANALOG SPECIFICATIONS (ta = -40C to 85C; TV+, RV+ = 5.0V +5%; GND = 0V) Parameter Min Typ Max | Units Driver Performance Monitor MTIP/MRING Sensitivity: Differential Voltage Required for Detection - 0.60 - V Receiver RTIP/RRING Input Impedance - 50k - Q Sensitivity Below DSX (O0dB = 2.4V) -13.6 - - dB Data Decision Threshold T1, DSX-1 (Note 24) 60 65 70 % of peak T1, DSX-1 (Note 25) 53 65 77 % of peak T1, FCC Part 68 and E1 (Note 26) 45 50 55 % of peak Data Decision Threshold T1 - 65 - % of peak E1 - 50 - % of peak Allowable Consecutive Zeros before LOS 160 175 190 bits Receiver Input Jitter Tolerance (Note 27) 10kHz - 100kHz 0.4 - - Ul 2kHz 6.0 - - Ul 10Hz and below 300 - - Ul Loss of Signal Threshold (Note 28) 0.25 0.30 0.50 V Notes: 24. For input amplitude of 1.2 Vpk to 4.14 Vpk. 25. For input amplitude of 0.5 Vpk to 1.2 Vpk and from 4.14 Vpk to RV+. 26. For input amplitude of 1.05 Vpk to 3.3 Vpk. 27. Jitter tolerance increases at lower frequencies. See Figure 11. 28. LOS goes high after 160 to 190 consecutive zeros are received. A zero is output on RPOS and RNEG (or RDATA) for each bit period where the input signal amplitude remains below the data decision threshold. The analog input squelch circuit operates when the input signal amplitude above ground on the RTIP and RRING pins falls within the squelch range long enough for the internal slicing threshold to decay within this range. Operation of the squelch causes zeros to be output on RPOS and RNEG as long as the input amplitude remains below 0.25V. During receive LOS, pulses greater than 0.25V in amplitude may be output on RPOS and RNEG. LOS returns low after the ones density reaches 12.5% (based upon 175 bit periods starting with a one and containing less than 100 consecutive zeros) as prescribed in ANSI T1.231-1993. DS40F2 54D mn EH EGD aD a lH manawa nn CS61535A T1 SWITCHING CHARACTERISTICS (1A = -40C to 85C; TV+, RV+ = 5.0V +5%: GND = OV; Inputs: Logic 0 = OV, Logic 1 = RV+; See Figures 1, 2, & 3) Parameter Symbol Min Typ Max | Units Crystal Frequency (Note 29) fc - 6.176000 - MHz ACLKI Duty Cycle towh3/tows 40 - 60 % ACLKI Frequency (Note 30) faclki - 1.544 - MHz RCLK Duty Cycle (Notes 31, 32) | towht/tpw1 - 78 - % - 29 - % RCLK Cycle Width (Note 32) tow1 320 648 980 ns tpwht 130 190 240 ns tow 100 458 850 ns Rise Time, All Digital Outputs (Note 33) tr - - 85 ns Fall Time, All Digital Outputs (Note 33) tf - - 85 ns TPOS/TNEG (TDATA) to TCLK Falling Setup Time tsu2 25 - - ns TCLK Falling to TROS/TNEG (TDATA) Hold Time the 25 - - ns RPOS/RNEG Valid Before RCLK Falling (Note 34) tsu4 150 274 - ns RDATA Valid Before RCLK Falling (Note 35) tsut 150 274 - ns RPOS/RNEG Valid Before RCLK Rising (Note 31) tsu4 150 274 - ns RPOS/RNEG Valid After RCLK Falling (Note 34) tht 150 274 - ns RDATA Valid After RCLK Falling (Note 35) tht 150 274 - ns RPOS/RNEG Valid After RCLK Rising (Note 31) tht 150 274 - ns TCLK Frequency ftelk - 1.544 - MHz TCLK Pulse Width (Notes 12, 31, 34, 36, 37) towh2 80 - 500 ns (Notes 35, 36, 37) 150 - 500 ns Notes: 29. Crystal must meet specifications described in CXT6176/CXT8192 data sheet. 30. ACLKI provided by an external source or TCLK, but not RCLK. 31. Hardware Mode, or Host Mode (CLKE = 0). 32. RCLK cycle width will vary with extent by which pulses displaced by jitter. Specified under worst case jitter conditions: 0.4 Ul AMI data displacement for T1 and 0.2 UI AMI data displacement for E1. 33. At max load of 1.6 mA and 50 pF. 34. Host Mode (CLKE = 1). 35. Extended Hardware Mode. 36. The maximum TCLK burst rate is 5 MHz and tpwa(min) = 200 ns. The maximum gap size that can be tolerated on TCLK is 12 VI. 37. The transmitted pulse width does not depend on the TCLK duty cycle. | tow1 | | bl > EXTENDED HARDWARE RCLK MODE OR ' twnt HOST MODE | tsu1 im | | RPOS RNEG YX | pee RDATA a BPV | | | | | HARDWARE MODE OR RCLK Nf Rr vd (CLKE = 0) Figure 1. Recovered Clock and Data Switching Characteristics 6 DS40F24D mn EH EGD aD a lH manawa nn CS61535A E1 SWITCHING CHARACTERISTICS (tA = -40C to 85C; Tv+, RV+ = 5.0V +5%:; GND = OV; Inputs: Logic 0 = OV, Logic 1 = RV+; See Figures 1, 2, & 3) Parameter Symbol Min Typ Max | Units Crystal Frequency (Note 29) fe - 8.192000 - MHz ACLKI Duty Cycle towh3/tpw3 40 - 60 % ACLKI Frequency (Note 30) faclki - 2.048 - MHz RCLK Duty Cycle (Notes 31, 32) | town1/tow1 - 29 - % RCLK Cycle Width (Note 32) tow1 310 488 670 ns tpwh1 90 140 190 ns towlt 120 348 500 ns RCLK Cycle Width (Note 32) tow1 320 488 670 ns towh1 - 348 - ns towlt1 100 140 - ns Rise Time, All Digital Outputs (Note 33) tr - - 85 ns Fall Time, All Digital Outputs (Note 33) tf - - 85 ns TPOS/TNEG (TDATA) to TCLK Falling Setup Time tsu2 25 - - ns TCLK Falling to TROS/TNEG (TDATA) Hold Time the 25 - - ns RPOS/RNEG Valid Before RCLK Falling (Note 34) tsut 100 194 - ns RDATA Valid Before RCLK Falling (Note 35) tsut 100 194 - ns RPOS/RNEG Valid Before RCLK Rising (Note 31) tsut 100 194 - ns RPOS/RNEG Valid After RCLK Falling (Note 34) thi 100 194 - ns RDATA Valid After RCLK Falling (Note 35) thi 100 194 - ns RPOS/RNEG Valid After RCLK Rising (Note 31) thi 100 194 - ns TCLK Frequency ftclk - 2.048 - MHz TCLK Pulse Width (Notes 31, 34, 36, 37) towh2 80 - 340 ns (Notes 35, 36, 37) 150 - 340 ns 90% Any Digital Output y 9 P 10% Figure 2. Signal Rise and Fall Characteristics t pw2 t pwh2 tow3 TCLK tsu2 the | tpwh3 rpostea (KX wan ES Figure 3a. Transmit Clock and Data Switching Figure 3b. Alternate External Clock Characteristics Characteristics DS40F2 74D mn EH EGD aD a lH manawa nn CS61535A SWITCHING CHARACTERISTICS (1a = -40 to 85C; TV+, RV+ = +5%; Inputs: Logic 0 = OV, Logic 1 = RV+) Parameter Symbol Min Typ Max Units SDI to SCLK Setup Time tdc 50 - - ns SCLK to SDI Hold Time tedh 50 - - ns SCLK Low Time tel 240 - - ns SCLK High Time teh 240 - - ns SCLK Rise and Fall Time tr, te - - 50 ns CS to SCLK Setup Time tec 50 - - ns SCLK to CS Hold Time (Note 38) | tech 50 - - ns CS Inactive Time tewh 250 - - ns SCLK to SDO Valid (Note 39) | _ teay - - 200 ns CS to SDO High Z tedz - 100 - ns Input Valid To PCS Falling Setup Time tsu4 50 - - ns PCS Rising to Input Invalid Hold Time tha 50 - - ns PCS Active Low Time tpcsl 250 - - ns Notes: 38. For CLKE = 0, CS must remain low at least 50 ns after the 16" falling edge of SCLK. 39. Output load capacitance = 50pF. towh tech tedh LEX RS RQ RRRLLLVI Sy RI MSBP DATA BYTE CONTROL BYTE Figure 4. Serial Port Write Timing Diagram 8 DS40F24D mn EH EGD aD a lH manawa nn CS61535A tedz SCLK KN ST tedv SDO I HIGH Z CLKE = 1 Figure 5. Serial Port Read Timing Diagram PCS tsu4 th4 t LENO/1/2, TAOS, pes! RLOOP, LLOOP, VALID INPUT DATA RCODE, TCODE Figure 6. Extended Hardware Mode Parallel Chip Select Timing Diagram DS40F2 9THEORY OF OPERATION Enhancements in CS61535A The CS61535A provides higher performance and more features than the CS61535 including: 50% lower power consumption, Internally matched transmitter output imped- ance for improved signal quality, e Optional AMI, B8ZS, HDB3 encoder/decoder or external line coding support, e Receiver AIS (unframed all ones) detection, e ANSI T1.231-1993 compliant receiver Loss of Signal (LOS) handling, e Transmitter TTIP and TRING outputs are forced low when TCLK is static, e The Driver Performance Monitor operates over a wider range of input signal levels. e Elimination of the requirement that a refer- ence clock be input on the ACLKI pin. Existing designs using the CS61535 can be converted to the higher performance, pin-compatible CS61535A if the transmit transformer is replaced by a pin-com- patible transformer with a new tums ratio and the 4.4 Q resistor used in El 75 Q applications is shorted. Introduction to Operating Modes The CS61535A supports three operating modes which are selected by the level of the MODE pin CS61535A as shown in Tables 1 and 2, Figure 7, and Figures A1-A3 of the Applications section. The CS61535A modes are Hardware Mode, Ex- tended Hardware Mode, and Host Mode. In Hardware and Extended Hardware Modes, discrete pins are used to configure and monitor the device. The Extended Hardware Mode provides a parallel chip select input which latches the control inputs allowing individual ICs to be configured using a common set of control lines. In the Host Mode, an external processor monitors and configures the de- vice through a serial interface. There are thirteen multi-function pins whose functionality is deter- mined by the operating mode (see Table 2). Transmitter The transmitter takes data from a T1 (or E1) ter- minal, attenuates jitter, and produces pulses of appropriate shape. The transmit clock, TCLK, and transmit data, TPOS & TNEG or TDATA, are supplied synchronously. Data is sampled on the falling edge of the input clock, TCLK. Either Tl (DSX-1 or Network Interface) or El G.703 pulse shapes may be selected. Pulse shap- ing and signal level are determined by "line length select" inputs as shown in Table 3. The MODE MODE EXTENDED EXTENDED FUNCTION | PIN | HARDWARE | HARDWARE |__HOST HARDWARE | HARDWARE HOST TRANSMITTER {3 TPOS TDATA TPOS MODE-PIN FLOAT, or 4 TNEG TCODE TNEG INPUT LEVEL <0.2V 2.5V >(RV+) - 0.2V 6 RNEG BPV RNEG BON TROL 7 RPOS RDATA RPOS INDIVIDUAL SERIAL RECEIVER/DPM| ,, DPM AIS DPM CONTROL CONTROL | LINES & PROCESSOR METHOD LINES PARALLEL | PORT 17 MTIP RCODE MTIP CHIP 18 MRING - MRING SELECT 18 - PCS - LINE CODE AMI, Wt ENCODER & NONE B8Zs, NONE 23 LENO LENO INT DECODER HDB3 CONTROL |-24 LEN1 LEN SDI AIS DETECTION NO YES NO 25 LEN2 LEN2 SDO DRIVER 26 RLOOP RLOOP cs PERFORN- YES NO YES 27 LLOOP LLOOP SCLK ANCE MONITOR 28 TAOS TAOS CLKE Table 1. Differences in Operating Modes Table 2. Pin Definitions 10 DS40F2CS61535A HARDWARE MODE TAOS LLOOP RLOOP LENO/1/2 | | | | CONTROL | TPOS TTP JITTER LINE DRIVER TRANSMIT TNEG ATTENUATOR e TRING ,)J TRANSFORMER MRING C862180B CS61535A DRIVER moniTor: }MTIP FRAMER > DPM CIRCUIT RPOS RTIP RECENE LINE RECEIVER je RNEG RRING | TRANSFORMER EXTENDED HARDWARE MODE TCODE RCODE TAOS LLOOP RLOOP PCS LENO/1/2 | | | | | | | v v v Y Y Y CONTROL TTIP TDATA JITTER TRANSMIT LINE DRIVER ATTENUATOR |_ TRING | TRANSFORMER HIGH SPEED CS61535A MUX (e.g., M13) AIS RTIP RDATA RECEIVE < DETECT LINE RECEIVER RRING | TRANSFORMER t BPV AIS HOST MODE uP SERIAL PORT t 5 CLKE | CONTROL CONTROL TPOS . TTIP TRANSMIT JITTER TNEG ATTENUATOR > LINE DRIVER | LRING TRANSFORMER CS62180B MRING | FRAMER MTIP CIRCUIT CS61535A DRIVER MONITOR > DPM RPOS RTIP RECEIVE RNEG LINE RECEIVER RRING TRANSFORMER Figure 7. Overview of Operating Modes DS40F2 11im iiws 7] iii? tf wali 4 LEN2 | LEN1 | LENO| OPTION SELECTED | APPLICATION 0 { { 0-133 FEET DSx-1 { 0 0 133-266 FEET ABAM { 0 { 266-399 FEET (AT&T 600B 1 1 0 399-533 FEET or 600C) { { { 533-655 FEET AT&T CB113 0 0 ' (CS61535A only) REPEATER QO QO QO CCITT G.703 2.048 MHz E1 0 { 0 | FCC Part 68, Option A | CSU NETWORK 0 { { ANSI T1.403 INTERFACE Table 3. Line Length Selection CS61535A line driver is designed to drive a 75 } equivalent load. For T1 DSX-1 applications, line lengths from 0 to 655 feet (as measured from the transmitter to the DSX-1 cross connect) are selectable. The five partition arrangement meets ANSI T1.102-1993 requirements when using ABAM cable. A typical output pulse is shown in Figure 8. These pulse settings can also be used to meet CCITT pulse shape requirements for 1.544 MHz operation. For T1 Network Interface applications, additional options are provided. Note that the optimal pulse width for Part 68 (324 ns) is narrower than the optimal pulse width for DSX-1 (350 ns). The CS61535A automatically adjusts the pulse width based upon the "line length " selection made. The El G.703 pulse shape is supported with line length selection LEN2/1/0=0/0/0. The pulse CS61535A width will meet the G.703 pulse shape template shown in Figure 9, and specified in Table 4. For El applications, the CS61535A driver pro- vides 14 dB of return loss during the transmission of both marks and spaces. This improves signal quality by minimizing reflections off the trans- mitter. Similar levels of return loss are provided for T1 applications. The CS61535A transmitter will detect a failed TCLK, and will force the TTIP and TRING out- puts low. NORMALIZED AMPLITUDE CS61535A ~ OUTPUT / PULSE SHAPE , YY 0.5 - | | | | 0 250 500 750 1000 TIME (nanoseconds) Figure 8. Typical Pulse Shape at DSX-1 Cross Connect For shielded twisted pair, 1200 load and transformer specified in Application Section. For coaxial cable, 750 load and transformer specified in Application Section. pulses at the nominal half amplitude Nominal peak voltage of a mark (pulse) 2.37 V 3V Peak voltage of a space (no pulse) 0 +0.237 V 0 +0.30 V Nominal pulse width 244 ns Ratio of the amplitudes of positive and negative 0.95 to 1.05* pulses at the center of the pulse interval Ratio of the widths of positive and negative 0.95 to 1.05* * When configured with a 0.47 uF nonpolarized capacitor in series with the TX transformer primary as shown in Figures A1, A2 and A3. Table 4. CCITT G.703 Specifications 12 DS40F2Percent of nominal peak voltage c69ns _, 120 110 100 90 80 50 10 -10 -20 Figure 9 . Mask of the Pulse at the 2048 kbps Interface When any transmit control pin (TAOS, LENO-2 or LLOOP) is toggled, the transmitter stabilizes within 22 bit periods. The transmitter will take longer to stabilize when RLOOP is selected be- cause the timing circuitry must adjust to the new frequency. Jitter Attenuator The jitter attenuator is designed to reduce wander and jitter in the transmit clock signal. It consists of a 32 bit FIFO, a crystal oscillator, a set of load capacitors for the crystal, and control logic. The jitter attenuator exceeds the jitter attenuation re- quirements of Publications 43802 and REC. G.742. A typical jitter attenuation curve is shown in Figure 10. The jitter attenuator works in the following man- ner. Data on TPOS and TNEG (or TDATA) are written into the jitter attenuators FIFO by TCLK. The rate at which data is read out of the FIFO and transmitted is determined by the oscillator. Logic circuits adjust the capacitive loading on the crys- CS61535A 10 p--\--- Ky --- Xb ------$-------1------ AT&T 62411 20 PA NOS Requirements go }------\------- | 40 b) Maximum Attenuation 50 Limit Rie Attenuation in dB | | 60 }------ 4+----+-;~~- Measured Performance -_ _ _- | | Frequency in Hz Figure 10. Typical Jitter Attenuation Curve tal to set its oscillation frequency to the average of the TCLK frequency. Signal jitter is absorbed in the FIFO. Jitter Tolerance of Jitter Attenuator The FIFO in the jitter attenuator is designed to neither overflow nor underflow. If the jitter am- plitude becomes very large, the read and write pointers may get very close together. Should the pointers attempt to cross, the oscillators divide by four circuit adjusts by performing a divide by 3 1/2 or divide by 4 1/2 to prevent the overflow or underflow. When a divide by 3 1/2 or 4 1/2 occurs, the data bit will be driven on to the line either an eighth bit period early or an eighth bit period late. When the TCLK frequency is close to the center frequency of the crystal oscillator, the high fre- quency jitter tolerance is 23 UI before the divide by 3 1/2 or 4 1/2 circuitry is activated. As the center frequency of the oscillator and the TCLK frequency deviate from one another, the jitter tol- erance is reduced. As this frequency deviation becomes large, the maximum jitter tolerance at high frequencies is reduced to 12 UI before the underflow/overflow circuitry is activated. In ap- plication, it is unlikely that the oscillator center frequency will be precisely aligned with the DS40F2 13CS61535A Data | RPOS Sampling & >> RNEG Clock Extraction |>* RCLK a . RTIP - Data 3 a Level 3 ~ Slicer RRING Edge Detector Clock Phase Selector iE Continuously ACLKI or Calibrated Oscillator in Jitter Delay Line Attenuator Figure 11. Receiver Block Diagram TCLK frequency due to allowable TCLK toler- ance, part to part variations, crystal to crystal variations, and crystal temperature drift. The os- cillator tends to track low frequency jitter so jitter tolerance increases as jitter frequency decreases. The crystal frequency must be 4 times the nomi- nal signal frequency: 6.176 MHz for 1.544 MHz operation; 8.192 MHz for 2.048 MHz applica- tions. Internal capacitors load the crystal, controlling the oscillation frequency. The crystal must be designed so that over operating tempera- ture, the oscillator frequency range exceeds the system frequency tolerance. Crystal Semiconduc- tor offers the CXT6176 & CXT8192 crystals, which yield optimum performance with the CS61535A. Transmit All Ones Select The transmitter provides for all ones insertion at the frequency of ACLKI. Transmit all ones is se- lected when TAOS goes high, and causes continuous ones to be transmitted on the line (TTIP and TRING). In this mode, the TPOS and TNEG (or TDATA) inputs are ignored. A TAOS request will be ignored if remote loopback is in effect. ACLKI jitter will be attenuated. TAOS is not available on the CS61535A when ACLKI is grounded. Receiver The receiver extracts data and clock from an AMI (Alternate Mark Inversion) coded signal and out- puts clock and synchronized data. The receiver is sensitive to signals over the entire range of cable lengths and requires no equalization or ALBO (Automatic Line Build Out) circuits. The signal is received on both ends of a center-tapped, center- grounded transformer. The transformer is center-tapped on the IC side. The clock and data recovery circuit exceeds the jitter tolerance speci- fications of Publications 43802, 43801, 62411 amended, TR-TS Y-000170, and CCITT REC. G.823. A block diagram of the receiver is shown in Fig- ure 11. The two leads of the transformer (RTIP and RRING) have opposite polarity allowing the receiver to treat RTIP and RRING as unipolar sig- nals. Comparators are used to detect pulses on RTIP and RRING. The comparator thresholds are dynamically established at a percent of the peak level (50% of peak for El, 65% of peak for T1; with the slicing level selected by LEN2/1/0). 14 DS40F2The receiver uses an edge detector and a continu- ously calibrated delay line to generate the recovered clock. The delay line divides its refer- ence clock, ACLKI or the jitter attenuators oscillator, into 13 equal divisions or phases. Con- tinuous calibration assures timing accuracy, even if temperature or power supply voltage fluctuate. The leading edge of an incoming data pulse trig- gers the clock phase selector. The phase selector chooses one of the 13 available phases which the delay line produces for each bit period. The out- put from the phase selector feeds the clock and data recovery circuits which generate the recov- ered clock and sample the incoming signal at appropriate intervals to recover the data. The jitter tolerance of the receiver exceeds that shown in Figure 12. 300 100 28 PEAK TO PEAK JITTER (unit intervals) 10 100 300 700 1k 10k 100k JITTER FREQUENCY (Hz) Figure 12. Input Jitter Tolerance of Receiver The CS61535A outputs a clock immediately upon power-up. The clock recovery circuit is cali- brated, and the device will lock onto the AMI data input immediately. If loss of signal occurs, the RCLK frequency will equal the ACLKI fre- quency. In the Hardware Mode, data at RPOS and RNEG is stable and may be sampled on the rising edge of the recovered clock. In the Extended Hardware Mode, data at RDATA is stable and may be sam- pled on the falling edge of the recovered clock. In CS61535A the Host Mode, CLKE determines the clock po- larity for which output data is stable and valid as shown in Table 5. MODE CLKE DATA CLOCK | Clock Edge for (pin 5) (pin 28) Valid Data LOW X RPOS RCLK Rising (<0.2V) RNEG RCLK Rising HIGH LOW RPOS RCLK Rising (>(V+) - 0.2V) RNEG RCLK Rising SDO SCLK Falling HIGH HIGH RPOS RCLK Falling (>(V+) - 0.2V) RNEG RCLK Falling SDO SCLK Rising MIDDLE X RDATA RCLK Falling (2.5V) X = Don't care Table 5. Data Output/Clock Relationship Jitter and Recovered Clock The CS61535A are designed for error free clock and data recovery from an AMI encoded data stream in the presence of more than 0.4 unit inter- vals of jitter at high frequency. The clock recovery circuit is also tolerant of long strings of zeros. The edge of an incoming data bit causes the circuitry to choose a phase from the delay line which most closely corresponds with the arrival time of the data edge, and that clock phase trig- gers a pulse which is typically 140 ns in duration. This phase of the delay line will continue to be selected until a data bit arrives which is closer to another of the 13 phases, causing a new phase to be selected. The largest jump allowed along the delay line is six phases. When an input signal is jitter free, the phase se- lection will occasionally jump between two adjacent phases resulting in RCLK jitter with an amplitude of 1/13 UIpp. These single phase jumps are due to differences in frequency of the incoming data and the calibration clock input to ACLKI. For T1 operation of the CS61535A, the instantaneous period can be 14/13 * 648 ns = 698 ns (1,662,769 Hz) or 12/13 * 648 ns = 598 ns (1,425,231 Hz) when adjacent clock phases are chosen. As long as the same phase is chosen, the DS40F2 15period will be 648 ns. Similar calculations hold for the E1 rate. The clock recovery circuit is designed to accept at least 0.4 UI of jitter at the receiver. Since the data stream contains information only when ones are transmitted, a clock/data recovery circuit must as- sume a zero when no signal is measured during a bit period. Likewise, when zeros are received, no information is present to update the clock recov- ery circuit regarding the trend of a signal which is jittered. The result is that two ones that are sepa- rated by a string of zeros can exhibit maximum deviation in pulse arrival time. For example, one half of a period of jitter at 100 kHz occurs in 5 us, which is 7.7 T1 bit periods. If the jitter ampli- tude is 0.4 UI, then a one preceded by seven zeros can have maximum displacement in arrival time, 1.e. either 0.4 UI too early or 0.4 UI too late. For the CS61535A, the data recovery circuit correctly assigns a received bit to its proper clock period if it is displaced by less than 6/13 of a bit period from its optimal location. Theoretically, this would give a jitter tolerance of 0.46 UI. The ac- tual jitter tolerance of the CS61535A is only slightly less than the ideal. In the event of a maximum jitter hit, the RCLK clock period immediately adjusts to align itself with the incoming data and prepare to accurately place the next one, whether it arrives one period later, or after another string of zeros and is dis- placed by jitter. For a maximum early jitter hit, RCLK will have a period of 7/13 * 648 ns = 349 ns (2,865,961 Hz). For a maximum late jitter hit, RCLK will have a period of 19/13 * 648 ns = 947 ns (1,055,880 Hz). Loss of Signal Receiver loss of signal is indicated upon receiv- ing 175 consecutive zeros. A digital counter counts received zeros based on RCLK cycles. A zero input is determined either when zeros are re- CS61535A ceived, or when the received signal amplitude drops below a 0.3 V peak threshold. The receiver reports loss of signal by setting the Loss of Signal pin, LOS, high. If the serial inter- face is used, the LOS bit will be set and an interrupt issued on INT. LOS will go low (and flag the INT pin again if serial I/O is used) when a valid signal is detected. Note that in the Host Mode, LOS is simultaneously available from both the register and pin 12. In a loss of signal state, the RCLK frequency will be equal to the ACLKI frequency since ACLKI is being used to calibrate the clock recovery circuit. Received data is output on RPOS and RNEG (or RDATA) regardless of LOS status. The LOS re- turns to logic zero when the ones density reaches 12.5% (based upon 175 bit periods staring with a one and containing less than 100 consecutive ze- ros) as prescribed in ANSI T1.231-1993. A power-up or manual reset will also set LOS high. Local Loopback The local loopback mode takes clock and data presented on TCLK, TPOS, and TNEG (or TDATA) and outputs it at RCLK, RPOS and RNEG (or RDATA). Local loopback is selected by taking pin 27 high, or LLOOP may be selected using the serial interface. The data on the trans- mitter inputs is transmitted on the line unless TAOS is selected to cause the transmission of an all ones signal instead. Receiver inputs are ig- nored when local loopback is in effect. The jitter attenuator is not included in the local loopback data path. Selection of local loopback overrides the chips loss of signal response. Remote Loopback In remote loopback, the recovered clock and data input on RTIP and RRING are sent through the jitter attenuator and back out on the line via TTIP and TRING. The recovered incoming signals are also sent to RCLK, RPOS and RNEG (or 16 DS40F2RDATA). Remote loopback is selected by taking pin 26 high, or RLOOP may be selected using the serial interface. Simultaneous selection of local and remote loopback modes is not valid (see Re- set). In the CS61535A Extended Hardware Mode, re- mote loopback occurs before the line code encoder/decoder, insuring that the transmitted sig- nal matches the received signal, even in the presence of received bipolar violations. The re- covered data will also be decoded and output on RDATA if RCODE is low. Driver Performance Monitor To aid in early detection and easy isolation of nonfunctioning links, the Hardware and Host Modes of the CS61535A are able to monitor transmit drive performance and report when the driver is no longer operational. This feature can be used to monitor either the devices perform- ance or the performance of a neighboring driver. The driver performance monitor indicator is nor- mally at a low (zero) logic level, and goes to high level upon detecting driver failure. In the Host Mode, DPM is available from both the register and pin 11. The driver performance monitor consists of an ac- tivity detector that monitors the transmitted signal when MTIP is connected to TTIP and MRING is connected to TRING. DPM will go high if the absolute difference between MTIP and MRING does not transition above or below a threshold level within a time-out period. Whenever more than one line interface IC resides on the same circuit board, the effectiveness of the driver performance monitor can be maximized by having each IC monitor performance of a neigh- boring device, rather than having it monitor its own performance. CS61535A Line Code Encoder/Decoder In Extended Hardware Mode, three line codes are available: AMI, B8ZS and HDB3. The input to the encoder is TDATA. The outputs from the de- coder are RDATA and BPV (Bipolar Violation Strobe). The encoder and decoder are selected us- ing pins LEN2, LEN1, LENO, TCODE and RCODE as shown in Table 6. LEN 2/1/0 000 010-111 TCODE LOW HDB3 B8ZS (Transmit Encoder Encoder Encoder AMI Selection) HIGH Encoder RCODE LOW HDB3 B8ZS (Receiver Decoder Decoder Decoder AMI Selection) HIGH Decoder Table 6. Selection of Encoder/Decoder Alarm Indication Signal In Extended Hardware Mode, the receiver sets the output pin AIS high when less than 9 zeros are detected out of 8192 bit periods. AIS returns low when 9 or more zeros are detected out of 8192 bits. Parallel Chip Select In Extended Hardware Mode, PCS can be used to gate the digital control inputs: TCODE, RCODE, LENO, LEN1, LEN2, RLOOP, LLOOP and TAOS. Inputs are accepted on these pins only when PCS is low. Changes in inputs will immedi- ately change the operating state of the device. Therefore, when cycling PCS to update the oper- ating state, the digital control inputs should be stable for the entire PCS low period. The control inputs are ignored when PCS is high. Power On Reset / Reset Upon power-up, the CS61535A is held in a static state until the supply crosses a threshold of ap- DS40F2 17CS61535A Data Input/Output DO xX D1 X D2 x D3 X D4 X DS Figure 13. Input/Output Timing proximately three Volts. When this threshold is crossed, the device will delay for about 10 ms to allow the power supply to reach operating voltage. After this delay, calibration of the delay lines used in the transmit and receive sections commences. The delay lines can be calibrated only if a refer- ence clock is present. The reference clock for the receiver is provided by ACLKI (or by the crystal oscillator if ACLKI is not present). The reference clock for the transmitter is provided by TCLK. The initial calibration should take less than 20 ms. In operation, the delay lines are continuously cali- brated, making the performance of the device independent of power supply or temperature vari- ations. The continuous calibration function foregoes any requirement to reset the line inter- face when in operation. However, a reset function is available which will clear all registers. In the Hardware and Extended Hardware modes, a reset request is made by simultaneously setting both RLOOP and LLOOP high for at least 200 ns. Reset will initiate on the falling edge of the reset request (falling edge of RLOOP and LLOOP). In the Host Mode, a reset is initiated by simultaneously writing RLOOP and LLOOP to the register. In either mode, a reset will set all registers to 0 and set LOS high. Serial Interface In the Host Mode, pins 23 through 28 serve as a microprocessor/microcontroller interface. One eight-bit register can be written to via the SDI pin or read from the SDO pin at the clock rate deter- mined by SCLK. Through this register, a host controller can be used to control operational char- acteristics and monitor device status. The serial port read/write timing is independent of the sys- tem transmit and receive timing. Data transfers are initiated by taking the chip se- lect input, CS, low (CS must initially be high). SCLK may be either high or low when CS in- itially goes low. Address and input data bits are clocked in on the rising edge of SCLK. Data on SDO is valid and stable on the falling edge of SCLK when CLKE is low, and on the rising edge of SCLK when CLKE is high. Data transfers are terminated by setting CS high. CS may go high no sooner than 50 ns after the rising edge of the SCLK cycle corresponding to the last write bit. For a serial data read, CS may go high any time to terminate the output. Figure 13 shows the timing relationships for data transfers when CLKE = 1. When CLKE = 0, data output from the serial port, SDO, is valid on the falling edge of SCLK. For CLKE = 1, data bit D7 is held to the falling edge of the 16th clock cycle; for CLKE = 0, data bit D7 is held to the rising edge of the 17th clock cycle. SDO goes to a high Read/Write Select; 0 = write, 1 = read ADDO |LSB of address, Must be 0 ADD1 | Must be 0 ADD2 | Must be 0 ADD3 | Must be 0 ADD4 | Must be 1 - Reserved - Must be 0 LSB, first bit | 0] RAW oon wn = Table 7. Address/Command Byte 18 DS40F2impedance state either after bit D7 is output or at the end of the hold period of data bit D7. An address/command byte, shown in Table 7, precedes a data register. The first bit of the ad- dress/command byte determines whether a read or a write is requested. The next six bits contain the address. The CS61535A responds to address 16 (0010000). The last bit is ignored. The data register, shown in Table 8, can be writ- ten to the serial port. Data is input on the eight clock cycles immediately following the ad- dress/command byte. Bits 0 and 1 are used to clear an interrupt issued from the INT pin, which occurs in response to a loss of signal or a problem with the output driver. If bits 0 or 1 are true, the corresponding interrupt is suppressed. So if a loss of signal interrupt is cleared by writing a | to bit 0, the interrupt will be reenabled by writing a 0 to bit 0. This holds for DPM as well. LSB: first bit in clr LOS | Clear Loss of Signal clr DPM| Clear Driver Performance Monitor LENO /Bit 0 - Line Length Select LEN1 /Bit 1 - Line Length Select LEN2 /Bit 2 - Line Lenght Select RLOOP | Remote Loopback LLOOP | Local Loopback TAOS | Transmit All Ones Select NO oR WN = O MSB: last bit in Table 8. Input Data Register Writing a "1" to either "Clear LOS" or "Clear DPM" over the serial interface has three effects: 1) the current interrupt on the serial interface will be cleared. (Note that simply reading the register bits will not clear the interrupt), 2) output data bits 5, 6 and 7 will be reset as appropriate, 3) future interrupts for the corresponding LOS or DPM will be prevented from occuring). CS61535A LSB: first bit in LOS |Loss of Signal DPM | Driver Performance Monitor LENO | Bit 0 - Line Length Select LEN1 | Bit 1 - Line Length Select LEN2 |Bit 2 - Line Lenght Select RON + Oo Table 9. Output Data Bits 0 - 4 Bits Status 5 6 7 0 O QO |Reset has occurred or no program input. 0 O 1 |TAOS in effect. 0 1 O |LLOOP in effect. 0 1 1 |TAOS/LLOOP in effect. 1 O O |RLOOP in effect 1 OQ 1 |DPMchanged state since last "clear DPM" occured. 1 1 OQ |LOS changed state since last "clear LOS" occured. 1 1 1 |LOS and DPM have changed state since last "clear LOS" and "clear DPM". Table 10. Coding for Serial Output Bits 5, 6, 7 Writing a "0" to either "Clear LOS" or "Clear DPM" enables the corresponding interrupt for LOS or DPM. Output data from the serial interface is presented as shown in Tables 9 and 10. Bits 2, 3 and 4 can be read to verify line length selection. Bits 5, 6 and 7 must be decoded. Codes 101, 110 and 111 (bits 5, 6 and 7) indicate LOS and DPM state changes. Writing a "1" to the "Clear LOS" and/or "Clear DPM" bits in the register also resets status bits 5, 6, and 7. SDO goes to a high impedance state when not in use. SDO and SDI may be tied together in appli- cations where the host processor has a bidirectional I/O port. DS40F2 19Power Supply The device operates from a single +5 Volt supply. Separate pins for transmit and receive supplies provide internal isolation. These pins should be connected externally near the device and decou- pled to their respective grounds. TV+ must not exceed RV+ by more than 0.3V. Decoupling and filtering of the power supplies is crucial for the proper operation of the analog cir- cuits in both the transmit and receive paths. A 1.0 uF capacitor should be connected between TV+ and TGND, and a 0.1 WF capacitor should be con- nected between RV+ and RGND. Use mylar or ceramic capacitors and place them as closely as possible to their respective power supply pins. A 68 uF tantalum capacitor should be added close to the RV+/RGND supply. Wire wrap bread- boarding of the line interface is not recommended because lead resistance and inductance serve to defeat the function of the decoupling capacitors. CS61535A STUER MeN UM NU msrla Confirm Optimum Schematic & Layout Before Building Your Board. For Our Free Review Service Call Applications Engineering. Call: (512)445-7222 20 DS40F2CS61535A PIN DESCRIPTIONS Hardware Mode ACLKI [/1 28 |] TAOS TCLK [j2 27 || LLOOP TPOS [/3 26 || RLOOP TNEG [|4 25|| LEN2 MODE [/5 24/| LEN1 RNEG [|6 23 |] LENO RPOS [/7 22/| RGND RCLK [/s 21/] RV+ XTALIN [/9 20/] RRING XTALOUT []1i0 i9|] RTIP DPM [/11 18|| MRING LOS [|12 17|| MTIP TTIP [)13 16{] TRING TGND [|14 15|] TV+ ACLKI TCLK TAOS TPOS LLOOP TNEG SS J RLOOP RNEG U5 4 3 2 1 28 27 26 251] LEN1 \ de oah/ RPOS dy a3 LENO RCLK (e {op 22 RGND XTALIN - a RV Sis oh \_ XTALOUT (11 19] RRING Jf 12 13 14 15 16 17 18 \ DPM __d Cl RTIP LOS MRING TTIP MTIP TGND TRING TV+ DS40F1 21CS61535A Extended Hardware Mode ACLKI [/|1 28 || TAOS TCLK [|2 27 || LLOOP TDATA [/3 26 || RLOOP TCODE |[\4 25 || LEN2 MODE [/5 24/| LEN1 BPV [|6 23 || LENO RDATA [/|7 22|| RGND RCLK |/s 21|| RV+ XTALIN [9 20[] RRING XTALOUT [10 19 |] RTIP AIS [|11 18[] PCS LOS [12 17|] RCODE TTIP [/13 16 |] TRING TGND [14 15(] TV+ ACLKI TCLK TDATA TCODE MODE SS pe TAOS LLOOP RLOOP LEN2 Vn O Bpy cs 4 9 2 1 2827 251) LENT RDATA RCLK 1 XTALIN xTaLouT d11 top view = ON 12 13 14 15 16 17 18 247] 3) LENO 22/ RGND 2a 20] RV+ 10h RRING AIS _/ LOS _ TTIP TGND _ RTIP PCS RCODE TRING TV+ 22 DS40F1CS61535A Host Mode ACLKI [/1 28 || CLKE TCLK [j2 27|| SCLK TPOS |[/3 26[| CS TNEG [\4 25|| SDO MODE [/5 24|| SDI RNEG [/6 23 |] INT RPOS [/7 22|| RGND RCLK [js 21[] RV+ XTALIN [/9 20|| RRING XTALOUT [| 10 19|| RTIP DPM [)11 i3([] MRING LOS [|12 17(] MTIP TTIP [13 16 |] TRING TGND [|14 15 |] TV+ ACLKI TCLK CLKE me es mie Wook fe ano _\ U5 4 3 2 3 28 27 26 ah /_ SDI 6 ert marae __ RPOS nei) INT _ t _ RCLK {f top 22} RGND _719 NL XTALIN ie = RV+ xTALOUT RRING 12 13 14 15 16 17 18 oon ae A nine MTIP TGND TRING TV+ DS40F1 23+ mB EE EGD 4D al maaan CS61535A Power Supplies RGND - Ground, Pin 22. Power supply ground for all subcircuits except the transmit driver; typically 0 Volts. RV+ - Power Supply, Pin 21. Power supply for all subcircuits except the transmit driver; typically +5 Volts. TGND - Ground, Transmit Driver, Pin 14. Power supply ground for the transmit driver; typically 0 Volts. TV+ - Power Supply, Transmit Driver, Pin 15. Power supply for the transmit driver; typically +5 Volts. TV+ must not exceed RV+ by more than 0.3 V. Oscillator XTALIN, XTALOUT - Crystal Connections, Pins 9 and 10. A 6.176 MHz (or 8.192 MHz) crystal should be connected across these pins. If a 1.544 MHz (or 2.048 MHz) clock is provided on ACLKI (pin 1), the jitter attenuator may be disabled by tying XTALIN, Pin 9 to RV+ through a | kQ resistor, and floating XTALOUT, Pin 10. Overdriving the oscillator with an external clock is not supported. Control ACLKI - Alternate External Clock Input, Pin 1. The CS61535A does not require a clock signal to be input on ACLKI when a crystal is connected between pins 9 and 10. If a clock is not provided on ACLKI, this input must be grounded. If ACLKI is grounded, the oscillator in the jitter attenuator is used to calibrate the clock recovery circuit and TAOS is not available. CLKE - Clock Edge, Pin 28. (Host Mode) Setting CLKE to logic 1 causes RPOS and RNEG to be valid on the falling edge of RCLK, and SDO to be valid on the rising edge of SCLK. Conversely, setting CLKE to logic 0 causes RPOS and RNEG to be valid on the rising edge of RCLK, and SDO to be valid on the falling edge of SCLK. CS - Chip Select, Pin 26. (Host Mode) This pin must transition from high to low to read or write the serial port. INT - Receive Alarm Interrupt, Pin 23. (Host Mode) _ Goes low when LOS or DPM change state to flag the host processor. INT is cleared by writing "Clear LOS" or "Clear DPM" to the register. INT is an open drain output and should be tied to the power supply through a resistor. 24 DS40F1rf yfyf ff yf fj maaan na CS61535A LENO, LEN1, LEN2 - Line Length Selection, Pins 23, 24 and 25. (Hardware and Extended Hardware Modes) Determines the shape and amplitude of the transmitted pulse to accommodate several cable types and lengths. See Table 3 for information on line length selection. Also controls the receiver slicing level and the line code in Extended Hardware Mode. LLOOP - Local Loopback, Pin 27. (Hardware and Extended Hardware Modes) Setting LLOOP to a logic 1 routes the transmit clock and data through to the receive clock and data pins. TPOS/TNEG (or TDATA) are still transmitted unless overridden by a TAOS request. Inputs on RTIP and RRING are ignored. MODE - Mode Select, Pin 5. Driving the MODE pin high puts the CS61535A line interface in the Host Mode. In the host mode, a serial control port is used to control the CS61535A line interface and determine its status. Grounding the MODE pin puts the CS61535A line interface in the Hardware Mode, where configuration and status are controlled by discrete pins. Floating the MODE pin or driving it to +2.5 V puts the CS61535A in Extended Hardware Mode, where configuration and status are controlled by discrete pins. When floating MODE, there should be no external load on the pin. MODE defines the status of 13 pins (see Table 2). PCS - Parallel Chip Select, Pin 18. (Extended Hardware Mode) Setting PCS high causes the CS61535A line interface to ignore the TCODE, RCODE, LENO, LEN1, LEN2, RLOOP, LLOOP and TAOS inputs. RCODE - Receiver Decoder Select, Pin 17. (Extended Hardware Mode) Setting RCODE low enables B8ZS or HDB3 zero substitution in the receiver decoder. Setting RCODE high enables the AMI receiver decoder (see Table 8). RLOOP - Remote Loopback, Pin 26. (Hardware and Extended Hardware Modes) Setting RLOOP to a logic 1 causes the recovered clock and data to be sent through the jitter attenuator (if active) and through the driver back to the line. The recovered signal is also sent to RCLK and RPOS/RNEG (or RDATA). Any TAOS request is ignored. Simultaneously taking RLOOP and LLOOP high for at least 200 ns initiates a device reset. SCLK - Serial Clock, Pin 27. (Host Mode) Clock used to read or write the serial port registers. SCLK can be either high or low when the line interface is selected using the CS pin. SDI - Serial Data Input, Pin 24. (Host Mode) Data for the on-chip register. Sampled on the rising edge of SCLK. SDO - Serial Data Output, Pin 25. (Host Mode) Status and control information from the on-chip register. If CLKE is high SDO is valid on the rising edge of SCLK. If CLKE is low SDO is valid on the falling edge of SCLK. This pin goes to a high-impedance state when the serial port is being written to or after bit D7 is output. DS40F1 25+ mB EE EGD 4D al maaan CS61535A TAOS - Transmit All Ones Select, Pin 28. (Hardware and Extended Hardware Modes) Setting TAOS to a logic 1 causes continuous ones to be transmitted at the frequency determined by ACLKI. TCODE - Transmitter Encoder Select, Pin 4. (Extended Hardware Mode) Setting TCODE low enables B8ZS or HDB3 zero substitution in the transmitter encoder. Setting TCODE high enables the AMI transmitter encoder . Data RCLK - Recovered Clock, Pin 8. The receiver recovered clock is output on this pin. RDATA - Receive Data - Pin 7. (Extended Hardware Mode) Data recovered from the RTIP and RRING inputs is output at this pin, after being decoded by the line code decoder. RDATA is NRZ. RDATA is stable and valid on the falling edge of RCLK. RPOS, RNEG - Receive Positive Data, Receive Negative Data, Pins 6 and 7. (Hardware and Host Modes) The receiver recovered NRZ digital data is output on these pins. In the Hardware Mode, RPOS and RNEG are stable and valid on the rising edge of RCLK. In the Host Mode, CLKE determines the clock edge for which RPOS and RNEG are stable and valid. See Table 5. A positive pulse (with respect to ground) received on the RTIP pin generates a logic 1 on RPOS, and a positive pulse received on the RRING pin generates a logic 1 on RNEG. RTIP, RRING - Receive Tip, Receive Ring, Pins 19 and 20. The AMI receive signal is input to these pins. A center-tapped, center-grounded, 2:1, step-up transformer is required on these inputs, as shown in Figure Al in the Applications section. Data and clock are recovered and output on RCLK and RPOS/RNEG or RDATA. TCLK - Transmit Clock, Pin 2. The1l.544 MHz (or 2.048 MHz) transmit clock is input on this pin. TPOS/TNEG or TDATA are sampled on the falling edge of TCLK. TDATA - Transmit Data, Pin 3. (Extended Hardware Mode) Transmitter NRZ input data which passes through the line code encoder, and is then driven on to the line through TTIP and TRING. TDATA is sampled on the falling edge of TCLK. TPOS, TNEG - Transmit Positive Data, Transmit Negative Data, Pins 3 and 4. (Hardware and Host Modes) Inputs for clock and data to be transmitted. The signal is driven on to the line through TTIP and TRING. TPOS and TNEG are sampled on the falling edge of TCLK. A TPOS input causes a positive pulse to be transmitted, while a TNEG input causes a negative pulse to be transmitted. TTIP, TRING - Transmit Tip, Transmit Ring, Pins 13 and 16. The AMI signal is driven to the line through these pins. In the CS61535A, this output is designed to drive a 75 load. A 1:1, 1:1.15 or 1:1.26 transformer is required as shown in Figure A1. 26 DS40F1Gn EE: Ef Ef 4D 4D a maaan! CS61535A Status AIS - Alarm Indication Signal, Pin 11. (Extended Hardware Mode) AIS goes high when unframed all-ones condition (blue alarm) is detected, using the detection criteria of less than three zeros out of 2048 bit periods. BPV- Bipolar Violation Strobe, Pin 6. (Extended Hardware Mode) BPV strobes high when a bipolar violation is detected in the received signal. B8ZS (or HDB3) zero substitutions are not flagged as bipolar violations if the B8ZS (or HDB3) decoder has been enabled. DPM - Driver Performance Monitor, Pin 11. (Hardware and Host Modes) DPM goes high if no activity is detected on MTIP and MRING. LOS - Loss of Signal, Pin 12. LOS goes high when 175 consecutive zeros have been received. For the CS61535A, LOS returns low when the ones density reaches 12.5% (based upon 175 bit periods starting with a one and containing less than 100 consecutive zeros) as prescribed by ANSI T1.231-1993. MTIP, MRING - Monitor Tip, Monitor Ring, Pins 17 and 18. (Hardware and Host Modes) These pins are normally connected to TTIP and TRING and monitor the output of a CS61535A. If the INT pin in the host mode is used, and the monitor is not used, writing "Clear DPM" to the serial interface will prevent an interrupt from the driver performance monitor. DS40F1 27+ mB EE EGD 4D al maaan CS61535A mm MILLIMETERS INCHES 28 15 4 ; DIM | MIN [NOM] MAX/ MIN | NOM| MAX Et 28 pin A | 3.94 | 4.32 | 5.08 |0.155|0.170|0.200 1 14) | Plastic DIP A1 | 0.51 | 0.76 | 1.02 |0.020| 0.030 |0.040 B | 0.36 | 0.46 | 0.56 |0.014/ 0.018 |0.022 B1 | 1.02 | 1.27 | 1.65 |0.040/0.050/0.065 C | 0.20 | 0.25 | 0.38 |0.008/0.010/0.015 D /36.45/|36.83/37.21/1.435/1.450/1.465 E1 /13.72|13.97/14.22/0.540/ 0.550 |0.560 e1 | 2.41 | 2.54 | 2.67 |0.095|0.100/0.105 eA (15.24| - |15.87/0.600| - [0.625 L [318/ - [3.81 /0.125) - |0.150 | o | - | 15] of | - | 15 NOTES: 1. POSITIONAL TOLERANCE OF LEADS SHALL BE WITHIN 0.25mm (0.010") AT MAXIMUM MATERIAL CONDITION, IN RELATION TO SEATING PLANE AND EACH OTHER. 2. DIMENSION eA TO CENTER OF LEADS WHEN FORMED PARALLEL. 3. DIMENSION E1 DOES NOT INCLUDE MOLD FLASH. 28-pin PLCC 28 E MILLIMETERS INCHES DIM | MIN |NOM| MAX MIN | NOM | MAX A | 4.20 | 4.45 | 4.57 /0.165|0.175/0.180 Al | 2.29 | 2.79 | 3.04 |0.090/0.110|0.120 B | 0.33 | 0.41 | 0.53 |0.013/0.016| 0.021 og a as es et = _ _ D/E | 12.32|12.45| 12.57 | 0.485|0.490/ 0.495 | D1 D1/E1/ 11.43]11.51 11.58 /0.450|0.453 | 0.456 | D D2/E2) 9.91 |10.41 10.92 0.390/0.410 | 0.430 e | 1.19 | 1.27 | 1.35 |0.047|0.050/ 0.053 1 [ C | 4 28 DS40F1CS61535A APPLICATIONS +5V +l gs ur sos BF Tir +5V LL 100 ka RGND 4 4s ~ TGND s 28, CLKE RV+ TV+ sci k 22 Control 1 ACLKI cs _ 26 uP & 12 Los INT |-23 +I Monitor Serial 11 24 < DPM SDI<=*__ Port spo |-25 5] RV+ L5]MoDE cs61535A 3-4 7 | RPos IN RTIP 6 HOST F < RNEG MODE = RECEIVE rame 8 | RCLK LINE Format Encoder/ 3 TPOS RRING Decoder 4. TNEG 5 mTip 17 TCLK MRING 8 | 9.47 wF 47 9 tana | 1611 1) 24 XTALIN I TRANSMIT XTL== 10 13 LINE | XTALOUT Bonn tonp TTP F F DEVICE FREQUENCY CABLE R1&2 Transmit MHz Qa Qa Transformer 1.544 100 200 1:1.15 CS61535A 2.048 120 240 1:1.26 2.048 75 150 1:1 Figure Al. Host Mode Configuration Line Interface Figures Al-A3 show the typical configurations for interfacing the I.C. to a line through transmit and receive transformers. The receiver transformer is center tapped and center grounded with resistors between the center tap and each leg on the I.C. side. These resistors provide the termination for the line. Figures Al-A3 show a 0.47 UF capacitor in series with the transmit transformer primary. This ca- pacitor is needed to prevent any buildup in the core of the transformer due to any DC imbalance that may be present at the differential outputs, TTIP and TRING. If DC saturates the trans- former, a DC offset will result during the transmission of a space (zero) as the transformer tries to dump the charge and return to equilib- rium. The blocking capacitor will keep DC current from flowing in the transformer. Selecting an Oscillator Crystal Specific crystal parameters are required for proper operation of the CS61535A. It is recom- mended that the CXT6176 from Crystal DS40F2 297 araze & #58 11) 2? aa CS61535A 45V pew 0.1 pF T 1.0 uF RGND ot 15 TGND 28 TAOS RV+ TV+ 1] ACLKI Contr 26.) RLOOP LENO 23 Line Monitor 27, LLOoP LEN1 24 Length 12 Los LEN2 25 Setting | ppm 5 19 cT 21 _p-2{MODE C861535A RTIP = IN Ri = = RECEIVE <7] Rpog HARDWARE c = 2 LINE 6 | RNEG MODE 20 = RRING Frame 8 Format RCLK Encoder/ 3, TPOS MTIP 7 Decoder 4 18 TNEG MRING 0.47 uF 25! TCLK TRING te | S| TRANSMIT 13 LINE XTALIN TTP XTLE= 40 ~ToIY XTALOUT BeND TGND 2 Figure A2, Hardware Mode Configuration 4+5V th gg ur 01 pF Tio RGND 24 15 TGND 17 RCODE RV+ TV+ 18,1 pos 6 Bpv LENO 29 Line 28, TAOS LEN1 \24 Length 1, 25 i Control ACLKI LEN2 Setting & 26, RLOOP Monitor 27, LLOOP _g61535A 19 cT et 12 | 109 IN RTIP = 11 als EXTENDED = RECEIVE HARDWARE = 5_| MODE = = LINE 4 MODE 20 = TCODE RRING F 7 | RDATA rame 8 Format RCLK Encoder/ 35) TDATA sRing 16 0 nf Decoder 2 TCLK I] | TRANSMIT 13 LINE TTIP aL = XTALIN == __10 | XTALOUT BenD TGND ie | Figure A3, Extended Hardware Mode Configuration 30 DS40F2CS61535A Semiconductor be used for T1 applications, and that the CXT8192 be used for E1 applications. Interfacing The CS61535A With the CS62180B TI Transceiver To interface with the CS62180B, connect the de- vices as shown in Figure A4. In this case, the CS61535A and CS62180B are in Host Mode con- trolled by a microprocessor serial interface. If the CS61535A is used in Hardware Mode, then the CS61535A RCLK output must be inverted before being input to the CS62180B. If the CS61535A is used in Extended Hardware Mode, the CS61535A RCLK output does not need to be inverted before being input to the CS62180B. TO HOST CONTROLLER ! V+ 100k 1.544 MHz CLOCK ACLKI CLKE SIGNAL SCLK TCLK [J TCLK SCLK sDO TPos [] TPOS cs SDI TNEG [J y TNEG sDO ve Les * MODE SDI RNEG INT RPOS RGND RCLK RV+ CS61535A RNEG [] RPOS RCLK CS62180B LITI Figure A4. Interfacing the CS61535A with the CS62180B (Host Mode) CS61534 Compatibility The CS61535A is pin compatible with the CS61534. The CS61535A has greater jitter toler- ance for both transmitter and receiver, and it provides more jitter attenuation starting at jitter frequencies of 6 Hz. The greater jitter tolerance and attenuation in the transmit path makes the CS61535A more suitable for CCITT demultiplex- ing applications where eight bits can be dropped from the clock/data stream at once. Similarly, these parts can be used in SONET applications with the addition of some external circuitry. The main differences of the CS61535A relative to the CS61534 is: 1) On the CS61535A, selection of LEN 2/1/0 = 0/0/0 changes the voltage at which the receiver accepts an input as a pulse (slicing level) from 65% to 50% of the peak pulse amplitude. Lower- ing the data slicing level will improve receiver sensitivity at long cable lengths when the data is jittered. A 50% slicing level will also improve crosstalk sensitivity for channels where received pulses do not have undershoot. 2) There are differences in the functionality of the ACLKI (ACLK) input on the CS61534 and CS61535A. ACKLI (ACLK) is used as the trans- mit clock in the transmit all ones (TAOS) mode. On the CS61535A, ACLKI is used as a calibra- tion reference for the receiver clock recovery circuit and therefore may not be supplied by RCLK. On the CS61534, ACLK may be supplied by RCLK . If an external clock is not provide on the ACLKI input of the CS61535A, the crystal oscillator is used to calibrate the receiver clock recovery circuit. 3) On the CS61535A, the Host Mode status regis- ter bits 5, 6 and 7 are encoded so that state changes on LOS and DPM may be reported. 4) RCLK on the CS61534 has a 50% duty cycle, while RCLK on the CS61535A has a duty cycle which is typically 30% or 70%. Also, the CS61535A RCLK duty cycle and instantaneous frequency vary with received jitter and may ex- hibit 1/13 UlIpp quantization jitter even when the incoming signal is jitter free. 5) The CS61535A requires 25 ns of setup time on TPOS and TNEG before the falling edge of TCLK and 25 ns of hold time on these inputs af- DS40F2 31ter the falling edge of TCLK. The CS61534 re- quires 50 ns of hold time on TPOS and TNEG after the falling edge of TCL, and 0 ns of setup time. 6) LOS occurs after 31 consecutive zeros on the CS61534. For the CS61535A LOS occurs after 175 zeros. 7) Since the CS61535A receivers are continu- ously calibrated, there is no need to issue a reset to initialize the receiver timing as with the CS61534. Using the CS61535A for SONET The CS61535A can be applied to SONET VT1.5 and VT2.0 interface circuits as shown in Fig- ure A5. The SONET data rate is 51.84 MHz, and has 6480 bits per frame (125 us per frame). An individual T1 frame (193 bits per frame) or PCM- CS61535A 30 frame (256 bits per frame) has its data mapped into the 6480 bit SONET frame. The mapping does not result in a uniform spacing between sucessive Tl (or El) bits. Rather, for locked WT applications, gaps as large as 24 T1 bit periods or 32 El bit periods can exist between successive bits. With floating VTs, the gaps can be even larger. The circuit in Figure A5 eliminates the demulti- plexing jitter in a two-step approach. The first step uses a FIFO which is filled at a 51.84 MHz rate (when T1 or El bits are present), and which is emptied at a sub-multiple of the 51.84 rate. The FIFO is emptied only when it contains data. When the FIFO is empty the output clock is not pulsed. The sub-multiple rate chosen should be slightly faster than the target rate (1.544 or 2.048 MHz), but as close to the target rate as possible. For 51.84 MHz Empty Write TCLK2] | Jitter [7 TCLK1 FIFO Clock TPOS Attenuator |__| Driver iE 6480 to TSER TNEG (or 256 bit) CS62180B Mapping < CS61535A Circuit RSER FIFO RSER > RPOS -RNEG Receiver i RCLK1 RCLK2 ROLK2 Figure AS. SONET Application 32 DS40F2locked VT operation, Table Al shows potential sub-multiple data rates, and the impact on those rates on the maximum gap in the output clock of the FIFO, and depth of FIFO required. FIFO depth will have to be increased for floating VT operation, with 8 bits of FIFO depth being added for each pointer alignment change that can occur. The objective that should be met in picking a FIFO depth and clock divider is keep the maxi- mum gap on the output of the FIFO at 12 bits or less. Twelve bits is the maximum jitter which can be input to the CS61535As jitter attenuator with- out causing the overflow/undeflow protection circuit to operate. The CS61535A then removes the remaining jitter from the signal. The receive path also requires a bit mapping (from 193 or 256 bits to 6480 bits). This mapping requires an input buffer with the same depth as use on the transmit path. This buffer also absorbs the output jitter generated by the CS61535As digital clock recovery. CS61535A Transformers Recommended transmitter and receiver trans- former specifications for the CS61535A are shown in Table A2. The transformers in Table A3 have been tested and recommended for use with the CS61535A. Refer to the "Telecom Trans- former Selection Guide" for detailed schematics which show how to connect the line interface IC with a particular transformer. In applications with the CS61535A where it is ad- vantageous to use a single transmitter transformer for both 75Q and 120 E1 applications, a 1:1.26 transforer may be used. Although transmitter re- turn loss will be reduced for 75Q. applications, the pulse amplitude will be correct across a 75 Q load. Target Rate Clock Resultant Maximum Gap FIFO Depth (MHz) Divider Rate (MHz) (us) bits Required 1.544 32 1.620 6.2 10 21 1.544 33 1.571 3.9 6 26 2.048 25 2.074 3.4 7 34 Table Al. Locked VT FIFO Analysis Parameter CS61535A Receiver CS61535A Transmitter Turns Ratio 1:2 CT+5% 1:141.5% for 750 Et 1:1.15 +5 % for 100 2 T1 1:1.26 + 1.5 % for 120 2 E1 Primary Inductance 600 wH min. @ 772 kHz 1.5 mH min. @ 772 kHz Primary Leakage Inductance 1.3 WH max. @ 772 kHz 0.3 WH max. @ 772 kHz Secondary Leakage Inductance 0.4 WH max. @ 772 kHz 0.4 WH max. @ 772 kHz Interwinding Capacitance 23 pF max. 18 pF max. ET-constant 16 V-us min. for T1 12 V-us min. for E1 16 V-us min. for T1 12 V-us min. for E1 Table A2, Transformer Specifications DS40F2 33CS61535A Application Turns Manufacturer Part Number Package Type Ratio(s) RX: 1:2CT Pulse Engineering PE-65351 1.5 kV through-hole, single 11 &E1 Schott 67129300 Bel Fuse 0553-0013-HC TX: 1:1.15 Pulse Engineering PE-65388 1.5 kV through-hole, single 1 Schott 67129310 Bel Fuse 0553-0013-RC TX: 1:1.26 Pulse Engineering PE-65389 1.5 kV through-hole, single E41 (75 & 120 Q) 1:1 Schott 67129320 Bel Fuse 0553-0013-SC RX &TX: 1:2CT Pulse Engineering PE-65565 1.5 kV through-hole, dual 11 1:1.15 Bel Fuse 0553-0013-7J RX &TX: 1:2CT Pulse Engineering PE-65566 1.5 kV through-hole, dual E1(75&120Q) | 1 1 6 Bel Fuse 0553-0013-8J RX &TX: 1:2CT Pulse Engineering PE-65765 1.5 kVsurface-mount, dual 11 1:1.15 Bel Fuse $553-0013-06 RX &TX: 1:2CT Pulse Engineering PE-65766 1.5 kV surface-mount, dual E1 (75 & 120 Q) " *e Bel Fuse $553-0013-07 RX: 1:2CT Pulse Engineering PE-65835 3 kV through-hole, single T1&E1 EN60950, EN41003 approved TX: Pulse Engineering PE-65839 3 kV through-hole, single E1 (75 & 120 Q) oh a3 ho oO EN60950, EN41003 approved Table A3. Recommended Transformers For The CS61535A 34 DS40F2A Cirrus Logic Company CDB61534, CDB61535, CDB61535A, CDB6158, CDB6158A, CDB61574, CDB61574A, CDB61575, CDB61577, CDB615304A, & CDB61305A Line Interface Evaluation Board Features Socketed Line Interface Device @ All Required Components for Complete Line Interface Evaluation Configuration by DIP Switch or Serial Interface LED Status Indicators for Alarm Conditions Support for Host, Hardware, and Extended Hardware Modes General Description The evaluation board includes a socketed line interface device and all support components necessary for evaluation. The board is powered by an external 5 Volt supply. The board may be configured for 100 twisted-pair T1, 75 coax E1, or 120 twisted-pair E1 operation. Binding posts are provided for line connections. Sev- eral BNC connectors are available to provide system clocks and data I/O. Two LED indicators monitor de- vice alarm conditions. The board supports all line interface operating modes. ORDERING INFORMATION: CDB61534, CDB61535. CDB61535A, CDB6158, CDB6158A, CDB61574, CDB61574A, CDB61575, CDB61577, CDB61304A, CDB61305A +5V Mode Select Circuit L o Reset Circuit Serial Interface |, Control Circuit Hardware Control Circuit CS61534, CS61535, CS61535A, LED Status +___| CS6158, Indicators CS6158A, O aTIP CS61574, : CS61574A, CS61577 O N RRING TCLK ce CS61304A - or [POs eH CS61305A (TDATA) = po TNEG c@ (TCODE) = | XTL oe RPOS Get (RDATA) == RCLK RNEG (BPV) Crysial Semiconductor Corporation P.O. Box 17847, Austin, TX 78760 (512) 445-7222 FAX: (512) 445-7581 SEP 95 DS40DB3 35POWER SUPPLY As shown on the evaluation board schematic in Figure 1, power is supplied to the evaluation board from an external +5 Volt supply connected to the two binding posts labeled +5V and GND. Transient suppressor D10 protects the compo- nents on the board from over-voltage damage and reversed supply connections. The recommended power supply decoupling is provided by C1, C2 and C3. Ceramic capacitor C1 and electrolytic ca- pacitor C2 are used to decouple RV+ to RGND. Capacitor C3 decouples TV+ to TGND. The TV+ and RV+ power supply traces are connected at the device socket U1. A ground plane on the compo- nent side of the evaluation board insures optimum performance. BOARD CONFIGURATION Pins on line interface device U1 with more than one pin name have different functions depending on the operating mode selected. Pin names not enclosed in parenthesis or square brackets de- scribe the Hardware mode pin function. Pin names enclosed in parenthesis describe the Ex- tended Hardware mode pin function. Pin names enclosed in square brackets describe the Host mode pin function. LINE INTERFACE EVALUATION BOARD Table 1 explains how to configure the evaluation board jumpers depending on the device installed and the desired operating mode. Mode selection is accomplished with slide switch SW1 and jump- ers JP2, JP6, and JP7. The CS61535A, CS61574A, CS61575, CS61577, CS61304A, and CS61305A support the Hardware, Extended Hardware, and Host operating modes. The CS61534, CS61535, and CS61574 support the Hardware and Host operating modes. The CS6158 and CS6158A only support the Hardware operating mode. Hardware Mode In the Hardware operating mode, the line inter- face is configured using DIP switch $2. The digi- tal control inputs to the device selected by S2 in- clude: transmit all ones (TAOS), local loopback (LLOOP), remote loopback (RLOOP), and trans- mit line length selection (LEN2,LEN1,LENO). Closing a DIP switch on S2 towards the label sets the device control pin of the same name to logic 1 (+5 Volts). Note that S2 switch positions TCODE and RCODE have no function in Hardware mode. In addition, the host processor interface connector JP1 should not be used in the Hardware mode. Two LED status indicators are provided in Hard- ware mode. The LED labeled DPM (AIS) illumi- nates when the line interface asserts the Driver JUMPER POSITION FUNCTION SELECTED JP1 : Connector for external processor in Host operating mode. JP2, JP6, JP7 A-A Extended Hardware operating mode. B-B Hardware or Host operating modes. JP3 IN Hardware or Extended Hardware operating modes. OUT Host operating mode. JPA c-C Connects the ACLKI BNC input to pin 1 of device. D-D Grounds the ACLKI BNC input through 510 resistor R1. JP5 E-E Transmit line connection for all applications except those listed for "F-F" on the next line. F-F 75Q. coax E1 applications using the Schott 12932/12532 or PE-65389/65566 at transformer T1. JP8 IN Shorts resistor R2 for all applications except those listed for "OUT" on the next line. OUT Inserts resistor R2 for 75Q coax E1 applications using the CS61534, 35, 58, 74, or 77. Table 1. Evaluation Board Jumper Settings 36 DS40DB3LINE INTERFACE EVALUATION BOARD +5V GND (OV) OO i+ IP RV+ Prototyping )_ Area RV+ R151.19 p di VVVt0 TCODE LENO/INT LEN1/SDI a LEN2/SDO a RLOOPICS LLOOP/SCLK TAOS/CLKE ooo dINT Om lo ol_SDI | o|_SDO CS TGND RGND RV+ RNEG (BPV) TPOS (TDATA) RPOS (RDATA) TNEG (TCODE) RLOOP [CS] LLOOP [SCLK] TAOS [CKLE] MODE DPM (AIS) XTALIN {CS6158/58A: RT} XTALOUT RTIP RRING TTIP MRING (PCS) TRING MTIP (RCODE) R13 (only included for CS6158/58A) 1kQ E1: CXT8192 = T1: CXT6176 10 (not included for CS6158/58A) {CS6158/58A: NC} RTIP Change R9 and R10 for E1 operation T2 (see Table 2) RTIP gm. T1 Zs R2 4.40 (Used only for E1 75Q oO o! SCLK] 2 11 applications with the CS61534, RVs C861535, CS6158, CS61574, los | OR CS61577) Qi 2N2222 U1: CS861534, CS61535, LED CS61535A, CS6158, b3 CS6158A, CS61574, R6 CS861574A, CS61575, 4702 C861577, CS61304A, OR CS61305A HOST:3-1,6-8 EXT HW: 3-2, 6-7 an HW: 3-4, 6-5 Figure 1. Evaluation Board Schematic DS40DB3 37LINE INTERFACE EVALUATION BOARD Performance Monitor alarm. The LED labeled LOS illuminates when the line interface receiver has detected a loss of signal. Extended Hardware Mode In the Extended Hardware operating mode, the line interface is configured using DIP switch S82. The digital control inputs to the device selected by S2 include: transmit all ones (TAOS), local loopback (LLOOP), remote loopback (RLOOP), transmit line length selection (LEN2, LEN1, LENO), transmit line code (TCODE), and receive line code (RCODE). Closing a DIP switch (mov- ing it towards the S2 label) sets the device control pin of the same name to logic 1 (+5 Volts). Note that the TCODE and RCODE options are active low and are enabled when the switch is moved away from the S2 label. The parallel chip select input PCS is tied to ground in Extended Hard- ware mode to enable the device to be reconfig- ured when S2 is changed. In addition, the host processor interface connector JP1 should not be used in Extended Hardware mode. Two LED status indicators are provided in Ex- tended Hardware mode. The LED labeled DPM (AIS) illuminates when the line interface detects the receive blue alarm (AIS). The LED labeled LOS illuminates when the line interface receiver has detected a loss of signal. Host Mode In the Host operating mode, the line interface is configured using a host processor connected to the serial interface port JP1. The S2 switch posi- tion labeled CLKE selects the active edge of SCLK and RCLK. Closing the CLKE switch se- lects RPOS and RNEG to be valid on the falling edge of RCLK and SDO to be valid on the rising edge of SCLK as required by the CS2180B T1 framer. All other DIP switch positions on S2 should be open (logic 0) to prevent shorting of the serial in- terface signals. Resistor R15 is a current limiting resistor that prevents the serial interface signals from being shorted directly to the +5 Volt supply if any S2 switch, other than CLKE, is closed. Jumper JP3 should be out so the INT pin may be externally pulled-up at the host processor inter- rupt pin. Two LED status indicators are provided in Host mode. The LED labeled DPM (AIS) illuminates when the line interface asserts the Driver Per- formance Monitor alarm. The LED labeled LOS illuminates when the line interface receiver has detected a loss of signal. Manual Reset A manual reset circuit is provided that can be used in Hardware and Extended Hardware modes. The reset circuit consists of S1, R4, R16, C4, D8, and D9. Pressing switch $1 forces both LLOOP and RLOOP to a logic 1 and causes a reset. A reset is only necessary for the CS61534 device to calibrate the center frequency of the re- ceiver clock recovery circuit. All other line inter- face units use a continuously calibrated clock re- covery circuit that eliminates the reset require- ment. TRANSMIT CIRCUIT The transmit clock and data signals are supplied on BNC inputs labeled TCLK, TPOS(TDATA), and TNEG. In the Hardware and Host operating modes, data is supplied on the TPOS(TDATA) and TNEG connectors in dual NRZ format. In the Extended Hardware operating mode, data is sup- plied in NRZ format on the TPOS(TDATA) con- nector and TNEG is not used. The transmitter output is transformer coupled to the line through a transformer denoted as T1 in Figure 1. The signal is available at the TTIP and TRING binding posts. Capacitor C5 is the recom- mended 0.47 uF DC blocking capacitor. 38 DS40DB3LINE INTERFACE EVALUATION BOARD The evaluation board supports 100Q twisted-pair T1, 75Q coax El, and 120 twisted-pair El op- eration. The CDB61534, CDB61535, CDB6158, CDB61574, and CDB61577 are supplied from the factory with a 1:2 transmit transformer that may be used for all T1 and E1 applications. The CDB61535A, CDB6158A, CDB61574A, CDB61575, CDB61304A, and CDB61305A are supplied with a 1:1.15 transmit transformer in- stalled for T1 applications. An additional 1:1:1.26 transformer for El applications is provided with the board. This transformer requires JP5 to be jumpered across F-F for 75Q coax E1 applica- tions. The CDB61534, CDB61535, CDB6158, CDB61574, and CDB61577 require the JP8 jumper to be out for 75Q coax E1 applications. This inserts resistor R2 to reduce the transmit pulse amplitude and meet the 2.37 V nominal pulse amplitude requirement in CCITT G.703. In addition, R2 increases the equivalent load imped- ance across TTIP and TRING. RECEIVE CIRCUIT The receive line interface signal is input at the RTIP and RRING binding posts. The receive sig- nal is transformer coupled to the line interface de- vice through a center-tapped 1:2 transformer. The transformer produces ground referenced pulses of equal amplitude and opposite polarity on RTIP and RRING. The receive line interface is terminated by resis- tors R9 and R10. The evaluation boards are sup- plied from the factory with 200Q resistors for ter- minating 100Q T1 twisted-pair lines. Resistors R9 and R1O should be replaced with 240Q resis- tors for terminating 120Q E1 twisted-pair lines or 150Q resistors for terminating 75Q E1 coaxial lines. Two 2430 resistors and two 150Q resistors are included with the evaluation board for this purpose. The recovered clock and data signals are avail- able on BNC outputs labeled RCLK, RPOS(RDATA), and RNEG(BPYV). In the Hard- ware and Host operating modes, data is output on the RPOS(RDATA) and RNEG(BPV) connectors in dual NRZ format. In the Extended Hardware operating mode, data is output in NRZ format on the RPOS(RDATA) connector and bipolar viola- tions are reported on the RNEG(BPYV) connector. QUARTZ CRYSTAL A quartz crystal must be installed in socket Y1 for all devices except the CS6158 and CS6158A. A Crystal Semiconductor CXT6176 crystal is rec- ommended for T1 operation and a CXT8192 is recommended for El operation. The evaluation board has a CXT6176 installed at the factory and a CXT8192 is also provided with the board. The CDB6158 and CDB6158A have resistor R13 installed instead of a crystal. This connects the RT pin of the device to the +5 Volt supply. ALTERNATE CLOCK INPUT The ACLKI BNC input provides the alternate clock reference for the line interface device (ACLK for the CS61534) when JP4 is jumpered across C-C. This clock is required for the CS61534, CS61535, CS6158, and CS6158A op- eration but is optional for all other line interface devices. If ACLKI is provided, it may be desir- able to connect both C-C and D-D positions on JP4 to terminate the external clock source provid- ing ACLKI with the 51Q resistor R1. If ACLKI is optional and not used, connector JP4 should be jumpered across D-D to ground pin 1 of the de- vice through resistor R1. TRANSFORMER SELECTION To permit the evaluation of other transformers, Table 2 lists the transformer and line interface de- vice combinations that can be used in T1 and El DS40DB3 39LINE INTERFACE EVALUATION BOARD applications. A letter at the intersection of a row and column in Table 2 indicates that the selected transformer is supported for use with the device. The transformer is installed in the evaluation board with pin 1 positioned to match the letter illustrated on the drawing in Table 2. For exam- ple, the Pulse Engineering PE-65388 transformer may be used with the transmitter of the CS61575 device for 100@ T1 applications only (as indi- cated by note 3) when installed in transformer socket T1 with pin 1 at position D (upper right). PROTOTYPING AREA A prototyping area with power supply and ground connections is provided on the evaluation board. This area can be used to develop and test a vari- ety of additional circuits like a data pattern gener- ator, CS2180B framer, system synchronizer PLL, or specialized interface logic. EVALUATION HINTS 1. Properly terminate TTIP/TRING when evaluat- ing the transmit output signal. For more informa- tion concerning pulse shape evaluation, refer to the Crystal application note entitled "Measure- ment and Evaluation of Pulse Shapes in T1/E1 Transmission Systems." 2. Change the receiver terminating resistors R9 and R10 when evaluating El applications. Resis- tors R9 and R1O should be replaced with 2400 resistors for terminating 120Q E1 twisted-pair lines or 150 resistors for terminating 75Q El coaxial lines. Two 243Q resistors and two 1500 resistors are included with the evaluation board for this purpose. 3. Closing a DIP switch on S2 towards the label sets the device control pin of the same name to logic 1 (+5 Volts). 4. To avoid damage to the external host controller connected to JP1, all S2 switch positions (except CLKE) should be open. In the Host operating mode, the CLKE switch selects the active edge of SCLK and RCLK. 40 DS40DB3aan 7 ae misma nnn LINE INTERFACE EVALUATION BOARD LINE INTERFACE UNIT TRANSFORMER 304A (Turns Ratio) "2 34. | 35 35A | 58 | '58A 74,77) "74A | 775 ae RX|TX/RX|TX|RX|TX/RX|TX/RX|TX/RX/TX/RX/TX/RX/TX RX TX PE-65351 (1:2CT) AD AIDIA A DIA A DIA A A Schott 12930 (1:2CT) BIC|B.C/B BIC!|B BIC!|B B B PE-65388 (1:1.15) b b b Db? D5 Schott 12931 (1:1.15) Ce Ce Ce Cc Cc PE-65389 (1:1:1.26) D* D* D* D* p*> Schott 12932 (1:1:1.26) ct ct ct ct ct PE-64951 (dual 1:2CT) E E E E Schott 11509 (dual 4:2CT) E E E E PE-65565 (dual 1:1.15 & 1:2CT) ES ES ES ES ES Schott 12531 (dual 1:1.15 & 1:2CT) ES ES ES ES ES PE-65566 (dual 1:1:1.26 & 1:2CT) E4 E4 E4 E4 E45 Schott 12532 (dual 1:1:1.26 & 1:2CT) E4 E4 E4 E4 E+ NOTES: 1. A letter at the intersection of a row and column in Table 2 indicates that the selected transformer is supported for use with the device. The transformer is installed in the evaluation board with pin 1 po- sitioned to match the letter illustrated in the drawing to the left. 2. The receive transformer (RX) is soldered at location T2 on the evaluation board and is used for all applications. The transmit transformer (TX) is socketed at location T1 on the evaluation board and may be changed according to the application. 3. For use in 100 11 twisted-pair applications only. 4. For use in 75Q and 120Q E1 applications only. Place jumper JP5 in position F-F for 75Q E1 applications requiring a 1:1 turns ratio. 5. Transmitter return loss improves when using a 1:2 turns ratio trans- former with the appropriate transmit resistors. Table 2. Transformer Applications DS40DB3 41LINE INTERFACE EVALUATION BOARD TNEG J7 TPQS( TDATA } J4 TCLK J3 ACLKI JS al *5V +5V GND (ris Ria [| TAOS /CLKE S} LLGOP/SCLK Dg RLOOP/CS p10 te ver LENI/SD1 R17 R1G MODE LEMELINT rN CRYSTAL = RCODE GND Semiconductor Corporation = sa SMART Analog HOST 4P3 [] RRING CDRE1S74A \re ExT Hi pine TRING HW RRING FE | tj n Roard mpDe ce RTIP PINIZ Rid RS re vera [ |: Cy via 02 XK jpe c3 ONC = De DPM PING SP? uPA RTIP RI] | ,a( ATS) a1 PIN3 UPS () Piniy TELK F 4 ACLKI F ste LOS RE RS ut TTP J c PING Y! {]} 7] - L_ RNEG(BPY) RPOS(RDATA) eisz> PUK Fd JP4 | RE TTIP ! ~ RCLK 6 ul GND ve ] TRING Figure 2. Silk Screen Layer (NOT TO SCALE) DS40DB3 42OOCO00C0O0 olelelolelolelolelelelelelejelelelelerlele) oleleloreleleloleleleleleleleslelelelelelelele) ololelolelolelolelelelelelelelelelolelelerele) lolelelelelelerlelelelelelelelololelelelelelere) olelolololelelelelelelelelelolelelerelelelese) ol elelejolelelolelolelelerelolelelelelelerere) ojolololololelelelelejelelelelelelelelelelere) elelerelelelelelerelelelerere) olelololelelololelelelelejere) olelelolelelelelelelelelelese) OO000000000000 olelelolelolelelelerlelelele) el olererelololelelerele) LINE INTERFACE EVALUATION BOARD olelerolelo mae 00000000 9 fe) Oo Oo Oo oO Oo oO ie) oO Oo O al haye7 ale ae 43 Figure 3. Top Ground Plane Layer (NOT TO SCALE) DS40DB3