CPC5604ATR

CPC5604 Optical Data Access Arrangement I.C. Features • 56K Compatible • Transformerless Optical Design • Complete Ring Detector Circuit • Caller ID Signal Detection • Snoop Circuitry • Integrated Hybrid • Small 32-Pin Plastic Package • PCMCIA Compatible • PCB Space and Cost Savings • compatible with all modem speeds including V.90 • FCC compliant • Compatible with U.S. and International dial up Phone lines • CTR-21 Compliant Description The CPC5604 is a single package optical Data Access Arrangement (DAA) device in a low profile surface mount PCMCIA compatible package. With a few external components, the CPC5604 provides a full featured International 56K capable solution. This device is well suited for all 56K modems, voice mail systems, fax machines, computer telephony applications, remote data access, medical, and security systems. For International compliance, external passive component values can be changed or, the CPC5604 can be used in conjunction with the CPC5601 Programmable Driver for a host programmable International DAA. Applications • 56K Modems/Fax including PCMCIA • Computer Telephony • Voice Mail Systems • Security/alarm systems • Utility Meters • Vending machines • Voice Over IP • Network routers • PBX systems • Home Medical Devices • Plant monitoring equipment • PC Mother Boards • Set Top Boxes (Cable TV Modems) Approvals • UL1950/UL1459 • EN60950 Ordering Information Part # CPC5604A CPC5604ATR Description Data Access Arrangement, Tape and Reel Data Access Arrangement, Tape and Reel Block Diagram TIP+ Isolation Barrier Transmit Isolation Amplifier Tx+ TxTransmit Diff. Amplifier Transconductance Stage 2-4 Wire Hybrid AC/DC Termination Hookswitch VI Slope Control AC Impedance Control Current Limit Control OH RING Vref AGC RING- CID Vref AGC Receive Isolation Amplifier Rx+ Rx- Receive Diff. Amplifier CID/ RING MUX C S R Snoop Amplifier C S R SNOOP SNOOP ANDS-CPC5604-XXX www.clare.com 1 CPC5604 Table of Contents Table 1 - Performance Specifications ........................................................................................................................3 Table 1 - Performance Specifications (Continued) ....................................................................................................4 Table 2 - Package Pinout ..........................................................................................................................................5 Applications ................................................................................................................................................................6 North American Reference Design Schematic ....................................................................................................6 Table 3 - North American Reference Design Bill of Materials....................................................................................7 International Reference Design Schematic................................................................................................................8 Table 4 - International Reference Design Bill of Materials ........................................................................................9 CTR-21 Reference Design Schematic ....................................................................................................................10 Table 5 - Reference Design Schematic Bill of Materials ..........................................................................................11 CTR-21 with Exceptions Reference Design Schematic ..........................................................................................12 Table 6 - CTR-21 with Exceptions Reference Design Bill of Materials ..................................................................13 Introduction ..............................................................................................................................................................14 Ring Detection via Snoop Circuit ........................................................................................................................14 Caller ID (CID) Detection via Snoop Circuit ......................................................................................................14 Hook Switch Control ..........................................................................................................................................14 Transmit Signal ..................................................................................................................................................14 Receive Signal Path ................................................................................................................................................15 Transmit Signal Path ................................................................................................................................................15 Ring Signal Detection ..............................................................................................................................................16 Figure 3 - Caller ID Protocol ....................................................................................................................................17 DC Charcteristics......................................................................................................................................................17 Figure 4 - Outlook DC Resistance Tip/Ring Setup ..................................................................................................18 On-Hook Resistance ................................................................................................................................................18 Current Limiting ........................................................................................................................................................18 CTR-21 Compliance ................................................................................................................................................18 AC Characteristics ....................................................................................................................................................18 Differential and Single Ended Mode ........................................................................................................................19 Receive and Transmit Frequency Response ..........................................................................................................19 Figure 4C - Transmit Frequency Response Setup ..................................................................................................20 Figure 4D - Transmit Frequency Response Tx±......................................................................................................20 Distortion ..................................................................................................................................................................21 Figure 5C - Transmit Distortion Text Tx± to Tip/Ring Setup ....................................................................................22 Figure 5D - Transmit Distortion on Tip/Ring ............................................................................................................22 Trans-Hybrid Loss ....................................................................................................................................................23 2 www.clare.com XXX CPC5604 Table of Contents (Continued) Return Loss ..............................................................................................................................................................24 Snoop Mode Frequency Response..........................................................................................................................25 Snoop Mode Distortion ............................................................................................................................................26 Snoop Mode Common Mode Rejection Ratio (CMRR) ..........................................................................................27 Country Specific Component Values........................................................................................................................28 Interconnection to Rockwell 56K Chipset ................................................................................................................29 Interconnection to Lucent 56K Chipset ....................................................................................................................30 Mechanical Dimensions............................................................................................................................................31 XXX www.clare.com 3 CPC5604 Absolute Maximum Ratings are stress ratings. Stresses in excess of these ratings can cause permanent damage to the device. Functional operation of the device at these or any other conditions beyond those indicated in the operational sections of this data sheet is not implied. Exposure of the device to the absolute maximum ratings for an extended period may degrade the device and effect its reliability. Electrical Characteristics PARAMETER DC Characteristics Operating Voltage VCC Operating Current ICC Operating Voltage VDD Operating Current IDD On-Hook Characteristics DC Resistance (metallic) DC Resistance (longitudinal) Ring Signal Detection at 68 Hz* Ring Signal Detection at 15 Hz* Snoop Circuit Frequency Response* Snoop Circuit CMRR Ringer Equivalence Longitudinal Balance Off-Hook Characteristics AC Impedance* Longitudinal Balance 68.3 Return Loss MIN 4.75 3.5 10 10 5 28 600 60 40 TYP 5 -40 0.1B 600 26 MAX 5.25 15 5.25 5 4000 UNIT V mA V mA MΩ MΩ V V Hz dB REN dB Ω dB dB CONDITION Modem Side Modem Side From Tip and Ring Drawn from Tip and Ring Tip to Ring, 100VDC Applied 150VDC Applied from Tip and Ring to Earth GND Ring Signal Applied to Tip and Ring Ring Signal Applied to Tip and Ring 3dB Corner Frequency 120VRMS 60Hz Common Mode Signal on Tip/Ring Per FCC Part 68.3 Tip to Ring Tip and Ring to Ground, per FCC part Against 600Ω, 1800Hz 4 www.clare.com XXX CPC5604 Table 1 -Performance Specifications (continued) PARAMETER Transmit/Receive Characteristics Frequency Response* Trans-Hybrid Loss* Transmit Insertion Loss* Receive Insertion Loss* Average In-band Noise Harmonic Distortion Transmit Level* Receive Level* Rx+/Rx- Output Drive Current Tx+/Tx- Input Impedance Isolation Characteristics Isolation Surge Voltage Surge Rise Time Control Logic (OH, CID, RING) Input Threshold Voltage High Level Input Current Low Level Input Current Output High Voltage Output Low Voltage Isolation Voltage Tip/Ring Current (continuous) Total Package Dissipation Operational Temperature Storage Temperature Soldering Temperature (10 seconds Max) Unless Otherwise Noted all Specifications @ 25oC. * Refer to Typical Application Circuit. MIN 30 -1 -1 60 1500 2000 0.8 -100 VCC-0.4 — 10 — -20 -40 — TYP 30 0 0 -100 90 - MAX 4000 1 1 -80 0 0 0.5 120 2.0 -20 0.4 1500 120 1 +85 +125 +220 UNIT Hz dB dB dB dB dB dBm dBm mA kΩ VSURGE V/µs V µA µA V V VRMS mA W °C °C °C CONDITION 3dB corner frequency Against 600Ω resistive, 1800Hz 4kHz Flat bandwidth -3dBm, 600Hz, 2nd Harmonic Single Tone Sine Wave Single Tone Sine Wave Sink and Source Line Side to Modem Side No Damage via T/R 1MΩ to Ground 1MΩ to VCC XXX www.clare.com 3 CPC5604 Table 2 -Package Pinout 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 VCC TXF1 TXTX+ TX NC GND OH RING CID RXRX+ SNP+ SNPRXF RX BRTXF2 ZTX ZNT TXS BRNTS GAT REF DCS DCF ZDC BRRPB RXS VDD Pin # 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 Name VCC TXF1 TX TX+ TX NC GND OH RING CID Function Host power supply, +5 Volts +/-5%. TX isolation amplifier output. NEG differential transmit signal into DAA. POS differential transmit signal into DAA. TX differential amplifier input. Not Connected. Connect to host analog ground. Driving this signal low asserts the off-hook condition. Active low indicates an incoming half waved ring signal pulsed High to Low at the ring frequency-typically 20Hz. Driving this signal low places the Caller ID information on the RX pins when the DAA is on hook (OH is deasserted). NEG differential analog receive signal from the telephone line and must be AC coupled with a 0.1 uF capacitor. POS differential analog receive signal from the telephone line and must be AC coupled with a 0.1 uF capacitor. One of two differential snoop inputs. One of two differential snoop inputs. Receive photodiode amplifier output. Receive photoamplifier summing junction. Power supply for line side portion of CPC5604. Receive photodiode servo input. Sets receive LED prebias current. Return to bridge rectifier negative output. Sets electronic inductor DCR/Current Limit. DC Filter Point. VI slope control via external resistor. 1.25V internal voltage reference. Depletion MOSFET gate control. Receive signal input path via Tip and Ring. Return to bridge rectifier negative output. Receive photodiode amplifier input. Sets DAA impedance via external passive network. Transmit Transconductance gain setting pin. Receive photodiode amplifier output. Return to bridge rectifier negative output. 1 2 3 4 5 6 7 8 9 10 11 RX- 12 RX+ 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 SNP+ SNPRXF RX VDD RXS RPB BRZDC DCF DCS REF GAT NTS BRTXS ZNT ZTX TXF2 BR- 6 www.clare.com XXX XXX Applications VCC C8 R10 C10 0.001uF 500V R11 10K D1 1 2 2D 4 R19 12M 0.250W 3 + 10M TX- TX+ R2 200K R1 604K U1 0.1uF C1 0.1uF C2 0.1uF ~ - ~ SP1 P3100SB TIP G1 R7 150K R36 4.7Ω C3 0.1uF Q1 MOSFET 3 S CPC5602C OH 1 2 3 4 5 6 7 32 31 30 29 28 27 26 25 24 RING RING North American Reference Design Schematic CPC5604 R20 1.6M C11 0.47uF Tant CID RXR15 100 R16 8.2 R12 402K R17 300 C4 0.1uF RX+ R3 150K C24 0.01uF R13 806K .063W R14 806K .063W R18 604 www.clare.com C7 220pF R5 2000V 1.5M R4 1M R6 C6 220pF 1.5M 2000V C5 0.1uF 8 9 10 11 12 13 14 15 16 23 22 21 20 19 18 17 VCC TXF1 TXTX+ TX NC GND OH RING CID RXRX+ SNP+ SNPRXF RX BRTXF2 ZTX ZNT TXS BRNTS GAT REF DCS DCF ZDC BRRPB RXS VDD Rev: B Company: CP Clare Corp. Title: U.S. Reference Design ALL RESISTORS ARE .100W UNLESS OTHERWISE NOTED Drawn: JC/MG Date: 10/27/99 CPC5604 7 CPC5604 Table 3 - North American Reference Design Bill of Materials QTY. 1 1 1 1 1 1 2 2 1 1 1 2 1 1 1 1 1 1 5 2 1 1 1 1 1 1 32 Designation U1 Q1 R1 R18 R2 R4 R3, R7 R5, R6 R11 R12 R15 R13, R14 R16 R17 R10 R19 R20 R36 C1, C2, C3, C4, C5 C6, C7 C8 C10 C11 C24 D1 SP1 TOTAL Description CPC5604A CPC5602C 604k 1% Res. 604 ohm 1% Res. 200k 5% Res. 1M 5% Res 150k 5% Res. 1.5M 5% Res. 10 K 5% Res. 402k 1% Res. 100 ohm 5% Res. 806K 1% Res. 0.063W 8.2 5% Res. 1/8W 300 ohm 5% Res. 10M 5% Res. 12M 5% Res. 0.25W 1.6M 5% Res. 4.7 ohm 5% Res 1/8W 0.1 uf 50V 10% X7R 220 pf 2000V NPO 5% 0.1uf 50V 10% X7R 0.001uf 500V10% X7R 0.47uf 25V Tant 10% .010 uf 50V 10% X7R Bridge Rectifier Surge Protection Manufacturer Clare Clare Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Tecate Tecate Tecate Tecate Panasonic Tecate Shindengen Teccor Package Type 32 Lead SOIC SOT-223 ‘0603 ‘0603 ‘0603 0603 ‘0603 ‘1206 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘1206 ‘0805 ‘0603 ‘0805 1808 ‘0805 1206 SMD 0805 N/A D0-214AA 8 www.clare.com XXX International Reference Design Schematic XXX VCC C8 R1 604K R10 C10 0.001uF 500V R11 10K D1 1 2 2D 4 SP1 P3100SB 3 + R19 12M 0.250W 10M 0.1uF TXR2 200K U1 TX+ C1 0.1uF C2 0.1uF ~ - ~ TIP G1 R7 150K R36 4.7Ω OH C3 0.1uF 1 2 3 4 5 6 7 32 31 30 29 28 27 26 Q1 MOSFET 3 S CPC5602C RING R34 0 ohm R20 1.6M C11 0.47uF Tant CPC5604 25 24 RING CID RX- C4 0.1uF R15 100 R16 22.1 1/ W 8 RX+ R12 402K R17 300 C5 0.1uF R3 150K C24 0.01uF R13 806K .063W R14 806K .063W 8 9 10 11 12 13 14 15 16 23 22 21 20 19 18 17 VCC TXF1 TXTX+ TX NC GND OH RING CID RXRX+ SNP+ SNPRXF RX BRTXF2 ZTX ZNT TXS BRNTS GAT REF DCS DCF ZDC BRRPB RXS VDD C7 220pF R5 2000V 1.5M R4 1M R6 C6 220pF 1.5M 2000V U4 Z1* Z2* R24* 2 8.2K 0.250W 3 3 16 3 D2 * 2 14 13 3 590 12 BIT2 7 BRBIT3 BIT4 8 BIT6 BIT5 CPC5601 9 10 R31 Open R32 Open R33 12.1 11 R29 OPEN R30 Open C17 Open 0 ohm C16 Open R27 6 N/C R28 Open R18 604 Open BIT1 R25 C15 Open R26 0 ohm 2 B R22* A 15 2 0 Ohm R23 470 0.47uF 300V C14* 1 www.clare.com * Required for external ring detect only. VCC R21* 10K DATA_IN Rev: B Company: CP Clare Corp. Title: International Reference Design Drawn: JC/MG Date: 10/2799 OPTIONAL: SOFTWARE PROGRAMMABLE CIRCUIT ALL RESISTORS ARE .100W UNLESS OTHERWISE NOTED CPC5604 9 CPC5604 Table 4 - International Reference Design Bill of Materials QTY. 1 1 1 1 1 1 1 2 2 2 1 1 2 1 1 1 1 1 1 1 5 1 1 1 1 1 1 1 5 2 1 1 1 1 1 1 1 1 1 2 1 1 53 Designation U1 U4 Q1 R1 R18 R2 R4 R3, R7 R5, R6 R11, R21 R12 R15 R13, R14 R16 R17 R10 R19 R20 R23 R24 R22, R29, R30, R31, R32 R25 R26 R27 R28 R33 R34 R36 C1, C2, C3, C4, C5 C6, C7 C8 C10 C11 C14 C15 C16 C17 C24 SP1 Z1, Z2 D1 D2 TOTAL Description CPC5604A CPC5601D CPC5602C 604k 1% Res. 604 ohm 1% Res. 200k 5% Res. 1M 5% Res. 150k 5% Res. 1.5M 5% Res. 10 K 5% Res. 402k 1% Res. 100 ohm 5% Res. 806K 1% Res. 0.063W 22.1 1% Res. 1/8W 300 ohm 5% Res. 10M 5% Res. 12M 5% Res. 0.25W 1.6M 5% Res. 470 ohm 5% Res. 8.2k 5% Res. 0.25W Open 590 ohm 5% Res. 0 ohm Res. 0 ohm Res. Open 12.1 ohm 1% Res. 0 ohm 5% Res. 4.7 ohm 5% Res 1/8W 0.1 uf 50V 10% X7R 220 pf 2000V NPO 5% 0.1uf 50V 10% X7R 0.001uf 500V10% X7R 0.47uf 25V Tant 10% .47uf 300V Open 0.0047uf 50V 10% X7R Open for future use 0.01uf 50V 10% X7R Surge Protection Zener 20V Bridge Rectifier Diode BAS16 Manufacturer Clare Clare Clare Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Tecate Tecate Tecate Tecate Panasonic Tecate Tecate Tecate Teccor Rohm Shindengen Rohm Package Type 32 Lead SOIC SO16 SOT-223 ‘0603 ‘0603 ‘0603 0603 ‘0603 ‘1206 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘1206 ‘0805 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0805 1808 ‘0805 1206 SMD 1812 ‘0805 ‘0805 ‘0805 0805 D0-214AA SOT-23 N/A SOT-23 10 www.clare.com XXX CTR-21 Reference Design Schematic XXX VCC C8 R1 604K R10 C10 0.001uF 500V R11 10K D1 1 2 2D 4 R19 12M 0.250W 3 + 10M 0.1uF TX- U1 R2 200K TX+ C1 0.1uF C2 0.1uF ~ - ~ SP1 P3100SB TIP G1 R7 150K R36 4.7Ω C3 0.1uF Q1 MOSFET 3 S CPC5602C OH 1 2 3 4 5 6 7 32 31 30 29 28 27 26 25 24 RING RING CPC5604 R20 1.6M C11 0.47uF Tant CID RXR15 100 R16 22.1 R12 402K R17 300 C25 R18 604 C4 0.1uF RX+ R3 150K C24 0.01uF R13 806K .063W R14 806K .063W C5 0.1uF 8 9 10 11 12 13 14 15 16 23 22 21 20 19 18 17 VCC TXF1 TXTX+ TX NC GND OH RING CID RXRX+ SNP+ SNPRXF RX BRTXF2 ZTX ZNT TXS BRNTS GAT REF DCS DCF ZDC BRRPB RXS VDD www.clare.com C7 220pF R5 2000V 1.5M R4 1M R6 C6 220pF 1.5M 2000V R21 12.1 U2 6 CTRL 1 2 3 4 5 Rev: B Company: CP Clare Corp. Title: CTR21 Reference Design Drawn: JC/MG Date: 10/27/99 ALL RESISTORS ARE .100W UNLESS OTHERWISE NOTED CPC5604 11 CPC5604 Table 5 - CTR-21 Reference Design Bill of Materials QTY. 1 1 1 1 1 1 2 2 1 1 1 2 1 1 1 1 1 1 1 5 2 1 1 1 1 1 1 1 34 Designation U1 Q1 R1 R4 R18 R2 R3, R7 R5, R6 R11 R12 R15 R13, R14 R16 R17 R10 R19 R20 R21 R36 C1, C2, C3, C4, C5 C6, C7 C8 C10 C11 C24 D1 SP1 U2 TOTAL Description CPC5604A CPC5602C 604k 1% Res. 1M 5% Res. 604 ohms 1% Res. 200k 5% Res. 150k 5% Res. 1.5M 5% Res. 10 K 5% Res. 402k 1% Res. 100 ohm 5% Res. 806K 1% Res. 0.063W 22.1 5% Res. 1/8W 300 ohm 5% Res. 10M 5% Res. 12M 5% Res. .25W 1.6M 5% Res. 12.1 5% Res. 0.063W 4.7 ohm 5% Res 1/8 W 0.1 uf 50V 10% X7R 220 pf 2000V NPO 5% 0.1uf 50V 10% X7R 0.001uf 500V10% X7R 0.47uf 25V Tant 10% 0.01uf 50V 10% X7R Bridge Rectifier Surge Protection 4N35 Manufacturer Clare Clare Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Tecate Tecate Tecate Tecate Panasonic Tecate Shindengen Teccor Package Type 32 Lead SOIC SOT-223 ‘0603 0603 ‘0603 ‘0603 ‘0603 ‘1206 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘1206 ‘0805 ‘0603 ‘0603 ‘0805 1808 ‘0805 1206 SMD ‘0805 N/A D0-214AA 12 www.clare.com XXX CTR-21 with Exceptions Reference Design Schematic XXX VCC C8 R1 604K R10 C10 0.001uF 500V R11 10K D1 1 2 2D 4 R19 12M 0.250W 3 + 10M 0.1uF TX- U1 R2 200K TX+ C1 0.1uF C2 0.1uF ~ SP1 P3100SB ~ TIP G1 R7 150K R36 4.7Ω C3 0.1uF Q1 MOSFET 3 S CPC5602C OH 1 2 3 4 5 6 7 32 31 30 29 28 27 26 25 24 RING RING CPC5604 R20 1.6M C11 0.47uF Tant CID RXR15 100 R16 22.1 R12 402K R17 300 C4 0.1uF RX+ R3 150K C24 0.01uF R13 806K .063W R14 806K .063W C5 0.1uF 8 9 10 11 12 13 14 15 16 23 22 21 20 19 18 17 VCC TXF1 TXTX+ TX NC GND OH RING CID RXRX+ SNP+ SNPRXF RX BRTXF2 ZTX ZNT TXS BRNTS GAT REF DCS DCF ZDC BRRPB RXS VDD www.clare.com C7 220pF R5 2000V 1.5M R4 1M R6 C6 220pF 1.5M 2000V R21 12.1 R18 604 R22 0 ohm 6 5 U3 4 CTRL 1 5 CTRL 4 1 2 3 4 2 3 6 U5 6 5 C18 0.0047uF U2 R35 Open CTRL 1 2 3 Rev: B Company: CP Clare Corp. Title: CTR21 with Exceptions Reference Design Drawn: JC/MG Date: 10/27/99 CPC5604 ALL RESISTORS ARE .100W UNLESS OTHERWISE NOTED 13 CPC5604 Table 6 - CTR-21 with Exceptions Reference Design Bill of Materials QTY. 1 1 1 1 1 1 2 2 1 1 1 2 1 1 1 1 1 1 1 1 1 5 2 1 1 1 1 1 1 1 1 1 38 Designation U1 Q1 R1 R18 R2 R4 R3, R7 R5, R6 R11 R12 R15 R13, R14 R16 R17 R10 R19 R20 R21 R22 R35 R36 C1, C2, C3, C4, C5 C6, C7 C8 C10 C11 C24 D1 SP1 U2 U3 U5 TOTAL Description CPC5604A CPC5602C 604k 1% Res. 604 ohm 1% Res. 200k 5% Res. 1M 5% Res 150k 5% Res. 1.5M 5% Res. 10 K 5% Res. 402k 1% Res. 100 ohm 5% Res. 806K 1% Res. 0.063W 22.1 1% Res. 1/8W 300 ohm 5% Res. 10M 5% Res. 12M 5% Res. 0.25W 1.6M 5% Res. 12.1 1% Res. 0.063W 0 ohm Open 4.7 ohm 5% Res 1/8 W 0.1 uf 50V 10% X7R 220 pf 2000V NPO 5% 0.1uf 50V 10% X7R 0.001uf 500V10% X7R 0.47uf 25V Tant 10% 0.01uf 50V 10% X7R Bridge Rectifier Surge Protection 4N35 4N35 4N35 Manufacturer Clare Clare Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Meritek Tecate Tecate Tecate Tecate Panasonic Tecate Shindengen Teccor Package Type 32 Lead SOIC SOT-223 ‘0603 ‘0603 ‘0603 0603 ‘0603 ‘1206 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘0603 ‘1206 ‘0805 ‘0603 ‘0603 ‘0603 ‘0603 ‘0805 1808 ‘0805 1206 SMD 0805 N/A D0-214AA 14 www.clare.com XXX CPC5604 Introduction The LITELINKTM (CPC5604) is a single package International Data Access Arrangement solution that is designed to be used in a variety of telephone applications including high performance 56kbps (V.90) modems. The LITELINKTM uses advanced optical signal coupling techniques to provide the required electrical isolation between the telephone and the Customer Premises Equipment (CPE). The LITELINKTM differs from other solutions using optical or capacitive isolation techniques by including the barrier inside the IC package, thus eliminating the need for external optocouplers or high-voltage capacitors in the data path resulting in overall reduced board space. The LITELINKTM has been designed to meet or exceed the requirements of international regulatory agencies. For international PTT compliance external passive components can be changed to meet different country requirements. For added flexibility, a second device, the CPC5601, can be used in conjunction with the CPC5604 to offer a host programmable solution. The CPC5601 is programmed serially through the host’s microcontroller. Using the CPC5601 along with the CPC5604 eliminates the need to change external passive components allowing for a flexible, fully international DAA. Ring Detection via Snoop Circuit While in the on-hook state (OH deasserted), an internal multiplexer turns on a “snoop” circuit that actively monitors the phone line for two conditions: incoming ring signal and Caller ID (CID) information. The snoop circuit “snoops” the line continuously while drawing a low 2uA max. current from the telephone line thus meeting regulatory requirements. When the central office (CO) places a ring signal on the telephone line, 90VRMS max, the RING output is pulsed from High to Low for 2 seconds at the same frequency as the AC signal, typically 20Hz, and restored to High during the 4 second delay. The ring detection circuitry is designed to reject false signaling from pulse dialing circuits or noise on the line. Caller ID (CID) Detection via Snoop Circuit CID is a service offered by the telephone company to provide caller information (i.e. the caller’s telephone number) to the called party. The CID signal is present on the telephone line after the first ring burst is sent from the CO. After this first ring burst is detected by the host, the host asserts the CID line which automatically couples the snoop circuit to the RX outputs on the LITELINKTM. After the CID signal is processed by the host, the host will deactivate the CID signal. At this point the host can answer the call by asserting the OH signal. Note that when the LITELINKTM goes off-hook it automatically disconnects the snoop path from both RX and RING outputs. Signals appearing on the telephone line are now coupled through the optical isolation barrier in the LITELINKTM and not via the snoop path. Hook Switch Control The OH or off-hook input is used to place the DAA on or off-hook. When the input is High, the DAA is on-hook or ready to receive calls from the CO. In this mode the snoop circuitry is enabled as described above. Driving OH Low places the DAA off-hook allowing the CO supplied loop current to flow (120mA max.), indicating the DAA is answering or preparing to place a call. Transmit Signal Outgoing analog signals to be transmitted to the telephone lines are placed differentially on the TX+ and TXinputs of the CPC5604. Transmit level from the user device is limited to 0dBm or 2.1Vp-p. The differential transmit signal is converted to a single ended signal by the CPC5604. The transmit signal is transferred across an optical barrier by an electrical-optical-electrical amplifier, which is transparent to the user. Variations in gain due to electrical-optical-electrical efficiency are virtually eliminated by an on-chip automatic gain control circuit which sets the input to output gain of the photodiode amplifier to 1. This results in a TX insertion loss of +/- 1dB. XXX www.clare.com 15 CPC5604 Receive Signal Path (Refer to Block Diagram) Signals to and from the telephone line to the LiteLinkTM appear on Tip and Ring connections. The receive signal is extracted from the transmit signal via the 2-4 wire hybrid block. The receive signal is then converted to infrared light by the receive photodiode amplifier and LED front end. The intensity of the infrared light is modulated by the receive signal and this light is transferred across the electrical isolation barrier via reflective dome to a photodiode where the light is converted to a photocurrent. This photocurrent is a highly linear representation of the receive signal and is amplified and converted to a voltage. This single ended voltage is converted to a differential voltage signal where it is presented as RX+ and RXand connects to the receive inputs of the host data pump. Variations in gain due to quantum efficiency of the optics are virtually eliminated by an on chip AGC circuit which automatically sets the input to output gain of the photoamplifier to unity. This means that the receive signal on the telephone line is faithfully reproduced at the RX outputs in terms of amplitude to within 2dB of the received signal. Distortion at the RX outputs is -80dB maximum at a receive level of -3dB over the band of 30Hz-4kHz. Single supply operation requires that the RX outputs be biased at 2.5V DC, therefore, it is necessary to use 0.1uf blocking capacitors for coupling the receive signal to the host. Figures 2.4.A and 2.4.B. illustrate connection to the host differentially and single ended respectively. Figure 2A Connection To Host Differential (Receive) HOST DATA PUMP/CODEC CPC5604A LITELINKTM Transmit Signal Path (Refer to Block Diagram) Signals that are to be sent from the host to the telephone line are placed differentially on TX+ and TX-. The maximum value of the transmit signal should not exceed 0dBm or 2.18Vpp. The differential transmit signal is converted to a single ended signal by the LiteLinkTM. This signal is coupled to the transmit photodiode amplifier in a similar manner to the receive path. At the output of this amplifier the voltage signal is coupled to a voltage to current converter via a transconductance stage where the transmit signal modulates the telephone line loop current. As in the receive stage, the gain of the transmit photodiode amplifier is set to unity automatically thereby limiting insertion loss to 0±1dB. Figures 2C and 2D illustrate connection to the host differentially and single ended respectively. Figure 2B Connection To Host Single Ended (Receive) HOST DATA PUMP/CODEC CPC5604A LITELINKTM 0.1uF RX+ RX+ RXRX- SINGLE ENDED CONNECTION TO CPC5604A 0.1uF RX+ RX+ Figure 2C Connection To Host Differential (Transmit) HOST DATA PUMP/CODEC CPC5604A LITELINKTM 0.1uF RXRX- 0.1uf TXA1 TX- - DIFFERENTIAL CONNECTION TO CPC5604A TXA2 0.1uf TX+ + SINGLE ENDED CONNECTION TO CPC5604A 16 www.clare.com XXX CPC5604 Ring Signal Detection The snoop circuit actively monitors the telephone line for 2 conditions: 1. Incoming ring signal 2. Caller ID information Figure 2D Connection To Host Single Ended (Transmit) HOST DATA PUMP/CODEC CPC5604A LITELINKTM Care should be taken when using this equation since RRXF (R3), CS (C6 or C7), and RSNOOP (R5 or R6) affect receive gain and Caller ID gain. It is recommended that RRXF (R3) be set to the typical value and then after adjusting the ring detect threshold, check that CID gain is acceptable. Caller ID Detection Caller ID (CID) is a service offered by the telephone company to provide caller information (i.e. caller’s telephone number) to the called party. CID service is optional and signals only appear on the telephone lines of subscribers that pay for this feature. The CID information appears on the telephone line after the first ring burst is sent from the central office (CO). Some of the characteristics of the CID signal are summarized below: Parameter Signal Level Link Type Transmission Scheme Logical 1 (mark) Logical 0 (Space) Transmission Rate Data BER Bit Duration Value -13dBm Simplex, 2W Phase-coherent, FSK 1200±12Hz 2200± 22Hz 1200bps serial binary async < 10E -5 833±50uS (same for start/stop as well) 0.1uf TXA1 TX- - TXA2 0.1uf TX+ + SINGLE ENDED CONNECTION TO CPC5604A The Snoop circuit “snoops” the line continuously while the LiteLinkTM is in the on-hook mode. Current taken from the telephone line in the on-hook condition by the LITELINKTM is maintained at a low 2uA maximum thus meeting regulatory requirements for minimum on-hook impedance limitation. When the central office places the ring signal on the telephone line, that signal is coupled through a pair of RC circuits to a differential amplifier in the LiteLinkTM. Referring to Block Diagram, snoop capacitors connected to the SNP1/SNP2 pins provide a high voltage isolation barrier between the host and the telephone line while coupling the AC signals to the snoop amplifier. The ring signal is digitized and brought out to the RING pin where the host can qualify it as a valid ring signal. The ring detection threshold is dependent on the values of 3 external components: RRXF (R3), RSNOOP (R5 or R6), and CS (C6 or C7). The default values in the typical bill of materials reflects the parameters in the data sheet for typical operation. If it is desired to change the threshold, the values can be selected by using the equation: VRING(PEAK) = 330E-3 5RRXF (RSNOOP)2 + 1 (2πf CS)2 Full details about the CID signal can be found in Bellcore document TR-TSY-000030, issue 1/1988. Figure 2.7.A shows the CID timing diagram. Waveform #1 represents the Analog signals on the telephone line (amplitude not drawn to scale), waveform #2 is the digital RING detect output from the LiteLinkTM, waveform #3 is the CID input to the LiteLinkTM from the Host. After the first ring burst is detected by the host, the host enables the CID line which automatically couples the snoop circuit to the RX outputs on the LiteLinkTM. Where f = ring frequency typically 20Hz. XXX www.clare.com 17 CPC5604 Figure 3 Caller ID Protocol 2s 500ms 3s 475ms 2s DC characteristics The LiteLinkTM is designed to meet various country DC characteristics including the CTR-21 standard. The pins that control the VI characteristics and current limiting are designated ZDC and DCS. Meeting DC requirements are achieved by selecting the appropriate resistors RZDC (R16) and RDCS (R20) respectively. Resistor values can also be switched in and out with the CPC5601device or optocouplers which enables international compliance under software control. Suggested resistor values for various countries are listed in table 1. The VI profile on Tip and Ring is described by the following equation: VLINE = VBRIDGE + RDCS+12MΩ (RDCS) 0.5V+ (ILINE - 8mA)RZDC CALLER ID MESSAGE SINE WAVE RING 1ST RING 2ND RING CID This CID signal is then processed by the host and, after processing, the host will deactivate the CID signal. At this point the host can answer the call if desired by asserting the OH pin on the LiteLinkTM. It’s important to note that when the LiteLinkTM goes off-hook, it automatically disconnects the snoop path from both the RX and Ring outputs. Signals appearing on the telephone line are now coupled through the optical isolation barrier in the LiteLinkTM and not via the capacitors in the snoop path. CID gain from Tip and Ring to Rx+ and Rx- is determined by: GAIN = 10 RRXF (RSNOOP)2 + 1 (2πf CS)2 Where f = CID signal frequency For example, with RRXF = 75KW, RSNOOP = 1.4MW, CS = 220pF, and f = 600Hz calculated GAIN = 0.707 or a loss of -3dB at Rx+ and Rx-. This implies that the snoop frequency response is 600Hz. Gain is expressed in decibels by: Example: ILINE = 20mA, VBRIDGE = 1.2V, RDCS = 1.69MW, RZDC = 8W, VLINE = 6.0V. 18 www.clare.com XXX CPC5604 Figure 4 On-Hook DC Resistance Tip/Ring Setup TIP A + LITELINK DAA Circuit TM - 100VDC RING On-Hook Resistance Figure 4 shows the test setup for on-hook DC resistance. The battery is set to 100VDC and an ammeter is placed in series with the battery connection. When the DAA is in the on-hook state, the leakage current is obtained and then the battery voltage is divided by this current yielding the on-hook resistance. The LiteLinkTM is guaranteed to have a leakage current < 10uA at 100V which is equivalent to an on-hook resistance > 10MΩ thus meeting regulatory approvals. Current Limiting The LiteLinkTM includes a current limiting feature that is selectable via resistor RZDC (R16). The current limit value is set by the equation: 10 1V RZDC For US/Canada/Japan the recommended value for RZDC (R16) is 8Ω which yields a current limit value of 133mA. The current limiting feature is especially useful in the case where the host system is inadvertently connected to a digital PBX telephone port which usually has a very high current limit value. The current limiting capability will prevent damage to the LiteLinkTM in this scenario. 12 CTR-21 Compliance CTR-21 is the standard for connection of data communications equipment to the European telephone network. The maximum current limit requirement in CTR-21 (Section 4.7.1) is 60mA and can be selected by the following equation: ILM = 1V RZDC + 8mA Clare recommends current limit be set to 53mA using an RZDC value of 22Ω. Since VDD is regulated to +3.5V, excess power is dissipated in the external MOSFET package. Since the maximum off-hook line voltage and current in CTR-21 is 40V and 53mA respectively, the maximum power dissipated by the MOSFET is approximately 2.1W. AC Characteristics In a similar manner to the DC characteristics, AC termination impedance is set via RZNT (R18). For all applications, a 604W resistor for RZNT (R18) is required to reflect 600W to the CO. XXX www.clare.com 19 CPC5604 Differential and Single Ended Mode The LiteLinkTM is designed to support either differential or single ended signals on Tx and/or Rx pins. The decision of which topology to use is based on the particular chipset being used to drive the LiteLinkTM. For example, most Lucent modem chips require both differential receive and transmit ability, while most Rockwell devices require differential transmit and single ended receive. The LiteLinkTM supports a full 0dBm differential signal on its Tx inputs. Receive and Transmit Frequency Response Figures 4A and 4C show the test circuits for receive and transmit frequency response respectively. Figures Figure 4A Receive Frequency Response Setup Audio Precision System One Analyzer RX+ IN1 AP1 IN2 RX100K V TIP 500 RX LITELINK DAA Circuit TM 4B and 4D show the graphs for receive and transmit frequency response respectively. 40mA Loop Current 10H + 48V 600 V T/R 470 uF Audio Precision Generator -3dBm/ 20Hz-4kHz OH RING 500 10H INSERTION LOSS (dB) = 20 log (V RX /V ) T/R Figure 4B Receive Frequency Response Rx+ +3 +2.5 +2 +1.5 +1 +0.5 -0 Gain (dBm) -0.5 -1 -1.5 -2 -2.5 -3 -3.5 -4 -4.5 -5 20 50 100 200 Frequency (Hz) 500 1K 2K 4K 20 www.clare.com XXX CPC5604 Figure 4C Transmit Frequency Response Setup 40mA Loop Current TIP 500 Audio Precision Generator -3dBm/20Hz-4kHz IN1 LITELINK DAA Circuit TM 10H + 48V 50 V TX TX+ V T/R 600 AP1 IN2 Audio Precision System One Analyzer TXOH RING 500 10H INSERTION LOSS (dB) = 20 log (V T/R /V TX ) Figure 4D Transmit Frequency Response Tx± +3 +2.5 +2 +1.5 +1 +0.5 -0 Gain (dBm) -0.5 -1 -1.5 -2 -2.5 -3 -3.5 -4 -4.5 -5 20 50 100 200 Frequency (Hz) 500 1K 2K 4K XXX www.clare.com 21 CPC5604 Distortion Figures 5A and 5C show the test setup for receive and transmit distortion. Figures 5B and 5.D show the THD at 600Hz graphs for receive and transmit respectively. Transmit signal for this test is set to -9dBm. Figure 5A Receive Distortion Test Tip/Ring to Rx± Setup RX+ IN1 TIP 100K 40mA Loop Current Audio Precision System One Analyzer AP1 IN2 500 600 RXLITELINK DAA Circuit TM 10H + 48V 470 uF Audio Precision Generator -9dBm/ 600Hz OH RING 500 10H Figure 5B Receive Distortion on Rx± dB 22 www.clare.com XXX CPC5604 Figure 5C Transmit Distortion Test Tx± to Tip/Ring Setup 40mA Loop Current TIP 500 IN1 600 AP1 IN2 TXOH RING 500 10H 10H + 48V Audio Precision Generator -3dBm/600Hz 50 TX+ LITELINK DAA Circuit TM Audio Precision System One Analyzer Figure 5D Transmit Distortion on Tip/Ring dB Frequency (Hz) XXX www.clare.com 23 CPC5604 Trans-Hybrid Loss As shown in Figure 6A, the Audio Precision, AP1 injects a signal into the Tx inputs and measures the energy at Rx with Tip and Ring terminated by a 600Ω nominal impedance. The Tx input frequency is swept from 30Hz4000Hz and the amplitude of the signal is measured on the Rx inputs and graphed in Figure 6B. Figure 6A Trans-Hybrid Loss (THL) Test Setup 40mA Loop Current IN1 Audio Precision System One Analyzer AP1 IN2 RXOH Audio Precision Generator -3dBm/30Hz-4kHz 50 V TX+ RING TX TXTHL = 20 log (V /V ) RX TX 500 10H 500uf LITELINK DAA Circuit TM RX+ 100K V RX TIP 500 600 48V 10H + Figure 6B Trans-Hybrid Loss at Rx± with -3dBm Signal on Tx± Matched to 600Ω Impedance on T/R +0 -2 -4 -6 -8 -10 -12 -14 -16 THL (dBm) -18 -20 -22 -24 -26 -28 -30 -32 -34 -36 -38 -40 500 1K 1.5K 2K Frequency (Hz) 2.5K 3K 3.5K 4K 24 www.clare.com XXX CPC5604 Return Loss The return loss is a measure of impedance mismatch between a terminating impedance (DAA) and a source impedance (reference impedance). The AP measures the return loss vs. frequency with the addition of the bridge circuit show in Figure 7A. For this test, the referFigure 7A Return Loss Test Setup V X ence impedance is set by the 600Ω nominal impedance, ZREF. The impedance that this is to be compared to is across Tip and Ring connections. The AP sweeps frequency and graphs frequency vs. return loss as shown in Figure 7B. 40mA Loop Current TIP 500 10H Z REF 600 + LITELINK DAA Circuit TM 48V - 600 Audio Precision Generator 50 + OH A RING 500 10H - VGEN RL (dB) = 20 log VX V GEN +B- -A+ Audio Precision System One Analyzer *Note: 0.1% Component tolerances should be used for accurate measurements Figure 7B Return Loss -10 -12 -14 -16 -18 -20 -22 -24 -26 -28 -30 -32 -34 -36 -38 -40 -42 -44 -46 -48 -50 500 1K 1.5K 2K Frequency (Hz) 2.5K 3K 3.5K 4K RL (dBm) XXX www.clare.com 25 CPC5604 Snoop Mode Frequency Response Figure 8A can be used as a reference test setup for this test with the difference being that the DAA is now in the on-hook mode. In the on-hook mode, the snoop circuit path is the signal path from Tip and Ring to Rx through the capacitive barrier CS instead of the optical path. Snoop frequency response graph is shown in Figure 8B. Figure 8A Snoop Mode Frequency Response Setup RX+ IN1 TIP 100K V RX RXLITELINK DAA Circuit TM Audio Precision System One Analyzer AP1 IN2 V T/R 600 Audio Precision Generator RING CID Figure 8B Snoop Mode Frequency Response At Rx± +1 +0.8 +0.6 +0.4 +0.2 +0 -0.2 -0.4 -0.6 -0.8 Gain (dBm) -1 -1.2 -1.4 -1.6 -1.8 -2 -2.2 -2.4 -2.6 -2.8 -3 500 1K 1.5K 2K 2.5K 3K 3.5K 4K Frequency (Hz) 26 www.clare.com XXX CPC5604 Snoop Mode Distortion Figure 9A can be used for the snoop mode distortion test. Snoop mode operation requires that the DAA be in — the on-hook state and the CID pin asserted (driven Low). Distortion in the snoop mode is not critical since signals coupled through the snoop circuit are either 20Hz ring signals or FSK CID signals. A graph of THD+N for the snoop mode is shown in Figure 9B. Figure 9A Snoop Mode Distortion Setup RX+ IN1 Audio Precision System One Analyzer TIP 100K V RX RXLITELINK DAA Circuit TM AP1 IN2 V T/R 600 Audio Precision Generator -13dbm 1800Hz RING CID Figure 9B Snoop Mode THD + N dBm 500 1K 1.5K 2K 2.5K 3K 3.5K 4K Hz XXX www.clare.com 27 CPC5604 Snoop Mode Common Mode Rejection Ratio (CMRR) As a practical matter, CMRR is dependent on how well the external snoop network CS and RSNOOP are matched. It is recommended that capacitors CS (C6 or C7) be ceramic NPO (COG) type for excellent temperature stability and have a tolerance of 5% or less. Resistor tolerance for RSNOOP (R5 or R6) should also be at least 5% or better. Careful consideration should be taken related to PCB layout of the snoop network. Traces should be as short as possible and kept equidistant from one another. Spacing of 0.1” should be maintained between traces on the phone line side. If possible, traces should be routed away from large 60Hz fields to prevent noise inducement into the snoop circuit. Figure 10A shows the test setup for CMRR through the snoop signal path. For this test the LITELINKTM is onhook and the frequency is swept from 20Hz to 4kHz. Figure 10B is a graph of CMRR vs. frequency. Figure 10A Snoop Mode Common Mode Rejection Ratio Setup 40mA Loop Current Audio Precision System One Analyzer IN1 AP1 IN2 RXLITELINK DAA Circuit TM RX+ 100K V RX TIP 500 10H + V T/R 2.16uf RING 48V - CID 500uf 1% matched 500 600 Audio Precision Generator 0dbm 10H Figure 10B Common Mode Rejection +0 -2.5 -5 -7.5 -10 -12.5 -15 -17.5 -20 -22.5 -25 -27.5 CMRR -30 (dBm) -32.5 -35 -37.5 -40 -42.5 -45 -47.5 -50 -52.5 -55 -57.5 -60 20 50 100 200 Frequency (Hz) 500 1K 2K 4K 28 www.clare.com XXX CPC5604 Country Specific Component Values RZDC US/Far East CTR-21 8.2W 22.1W ZZNT 600W 600W CTR-21 Countries: • UK • France • Germany • Spain • Switzerland • Italy • Luxembourg • Holland • Belgium • Netherlands • Australia XXX www.clare.com 29 30 Conexant MCU L2800 ~Rly1(~OH) 70 RINGD 32 ~RLY4(~CALLID) 6 R1 10K .063W R3 20K .063W C1 0.1uF C2 0.1uF VCC CPC5604 Interconnection to Rockwell 56k Chipset Refer to LITELINK reference schematics for typical line side circuit details. R4 604K R5 200K U1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 VCC TXF1 TXTX+ TX NC GND OH RING CID RXRX+ SNP+ SNPRXF RX BRTXF2 ZTX ZNT TXS BRNTS GAT REF DCS DCF ZDC BRRPB RXS VDD 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 R2 10K .063W C3 0.1uF Conexant MDP R6764 CPC5604 www.clare.com XXX TXA1 30 TXA2 31 RiN 35 -6dB 1 C5 0.1uF -6dB 1 R3 150K C7 220pF R8 2000V 1.5M R4 1M R9 C6 220pF 1.5M 2000V Drawn: SM Company: CP Clare Corp. Date: 6/24/99 Rev: A Title: Interconnection to Conexant(Rockwell) (CPC5600A1X) Interconnection diagram is based on the Conexant(Rockwell) RC56D Chip solution. 1. Conexant Chipsets rely on a 6dB loss between MDP and tip and ring. This is solved by placing the R1, R2, R3, resistor circuit in the Transmit Path and the use of a single end of the differential receive. ALL RESISTORS ARE .100W UNLESS OTHERWISE NOTED Interconnection to Lucent 56k Chipset XXX VCC Refer to LITELINK reference schematics for typical line side circuit details Lucent Technologies Venus DSP1670_160_MQFP R1 604K R2 200K U1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 VCC TXF1 TXTX+ TX NC GND OH RING CID RXRX+ SNP+ SNPRXF RX BRTXF2 ZTX ZNT TXS BRNTS GAT REF DCS DCF ZDC BRRPB RXS VDD 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 OHRCN 61 RIDETN 43 CIDN 62 C1 0.1uF C2 0.1uF C3 0.1uF CPC5604 www.clare.com 31 Lucent Technologies CSP1034_MFQP R3 150K AOUTN 8 AOUTP 7 AINP 11 0dB 1 0dB 1 C4 0.1uF AINN 10 C5 0.1uF R4 1M C7 220pF R5 2000V 1.5M R6 C6 220pF 1.5M 2000V Drawn: SM Date: 6/24/99 Rev: A Company: CP Clare Corp. Title: Interconnection To Lucent (CPC5600A1X) CPC5604 1. Lucent chips expect a zero dB drop between the codec and Tip and Ring. ALL RESISTORS ARE .100W UNLESS OTHERWISE NOTED CPC5604 Mechanical Dimensions 32 Pin SOIC 10.287 + .254 (0.405 + 0.010) Recommended Pad Layout 11.380 (0.448) 0.635 (0.025) 0.330 (0.013) 9.730 (0.383) 1.650 (0.065) 7.239 + 0.051 (0.285 + 0.002) 0.635 x 45o (0.025 x 45o) 0.203 (0.008) 1.016 Typ. (0.040 Typ.) 0.635 + 0.076 (0.025 + 0.003) 1.981 + 0.051 (0.078 + 0.002) 0.330 + 0.051 (0.013 + 0.002) 9.525 + 0.076 (0.375 + 0.003) 0.051 + 0.051 (0.002 + 0.002) 7.493 + 0.076 10.363 + 0.127 (0.295 + 0.003) (0.408 + 0.005) 2.032 Typ. (0.080 Typ.) A Coplaner to A 0.08/(0.003) 32 PL. Dimensions mm (inches) 32 www.clare.com XXX Worldwide Sales Offices CLARE LOCATIONS Clare Headquarters 78 Cherry Hill Drive Beverly, MA 01915 Tel: 1-978-524-6700 Fax: 1-978-524-4900 Toll Free: 1-800-27-CLARE Clare Micronix Division 145 Columbia Aliso Viejo, CA 92656-1490 Tel: 1-949-831-4622 Fax: 1-949-831-4628 Clare Switch Division 4315 N. Earth City Expressway Earth City, MO 63045 Tel: 1-314-770-1832 Fax: 1-314-770-1812 EUROPE European Headquarters CP Clare nv Bampslaan 17 B-3500 Hasselt (Belgium) Tel: 32-11-300868 Fax: 32-11-300890 France Clare France Sales Lead Rep 99 route de Versailles 91160 Champlan France Tel: 33 1 69 79 93 50 Fax: 33 1 69 79 93 59 Germany Clare Germany Sales ActiveComp Electronic GmbH Mitterstrasse 12 85077 Manching Germany Tel: 49 8459 3214 10 Fax: 49 8459 3214 29 Italy C.L.A.R.E.s.a.s. Via C. Colombo 10/A I-20066 Melzo (Milano) Tel: 39-02-95737160 Fax: 39-02-95738829 Sweden Clare Sales Comptronic AB Box 167 S-16329 Spånga Tel: 46-862-10370 Fax: 46-862-10371 United Kingdom Clare UK Sales Marco Polo House Cook Way Bindon Road Taunton UK-Somerset TA2 6BG Tel: 44-1-823 352541 Fax: 44-1-823 352797 ASIA/PACIFIC Asian Headquarters Clare Room N1016, Chia-Hsin, Bldg II, 10F, No. 96, Sec. 2 Chung Shan North Road Taipei, Taiwan R.O.C. Tel: 886-2-2523-6368 Fax: 886-2-2523-6369 SALES OFFICES AMERICAS Americas Headquarters Clare 78 Cherry Hill Drive Beverly, MA 01915 Tel: 1-978-524-6700 Fax: 1-978-524-4900 Toll Free: 1-800-27-CLARE Eastern Region Clare 603 Apache Court Mahwah, NJ 07430 Tel: 1-201-236-0101 Fax: 1-201-236-8685 Toll Free: 1-800-27-CLARE Central Region Clare Canada Ltd. 3425 Harvester Road, Suite 202 Burlington, Ontario L7N 3N1 Tel: 1-905-333-9066 Fax: 1-905-333-1824 Western Region Clare 1852 West 11th Street, #348 Tracy, CA 95376 Tel: 1-209-832-4367 Fax: 1-209-832-4732 Toll Free: 1-800-27-CLARE Canada Clare Canada Ltd. 3425 Harvester Road, Suite 202 Burlington, Ontario L7N 3N1 Tel: 1-905-333-9066 Fax: 1-905-333-1824 http://www.clare.com Clare, Inc. makes no representations or warranties with respect to the accuracy or completeness of the contents of this publication and reserves the right to make changes to specifications and product descriptions at any time without notice. Neither circuit patent licenses nor indemnity are expressed or implied. Except as set forth in Clare’s Standard Terms and Conditions of Sale, Clare, Inc. assumes no liability whatsoever, and disclaims any express or implied warranty, relating to its products including, but not limited to, the implied warranty of merchantability, fitness for a particular purpose, or infringement of any intellectual property right. The products described in this document are not designed, intended, authorized or warranted for use as components in systems intended for surgical implant into the body, or in other applications intended to support or sustain life, or where malfunction of Clare’s product may result in direct physical harm, injury, or death to a person or severe property or environmental damage. Clare, Inc. reserves the right to discontinue or make changes to its products at any time without notice. Specification: ANDS-CPC5604-XX ©Copyright 2001, Clare, Inc. All rights reserved. Printed in USA. 6/26/01