Agilent HSDL-3603 IrDA® Data Compliant 4 Mbit/s Infrared Transceiver Data Sheet Features • Fully compliant to IrDA 1.4 Fast Infrared (FIR) from 9.6 kbit/s to 4 Mbit/s • Typical link distance > 1.5 m Description The HSDL-3603 is a low profile infrared transceiver module that provides interface between logic and IR signals for through-air, serial, half-duplex IR data-link. The module is fully compliant to IrDA Date Physical Layer Specifications v1.4 Fct Infrared (FIR) and IEC825Class I Eye Safe. The HSDL-3603 can be shut down completely to achieve very low power consumption. In the shutdown mode, the PIN diode will be inactive and thus producing very little photocurrent even under very bright ambient light. Such features are ideal for mobile devices that require low power consumption. Applications • Digital imaging – Digital still cameras – Photo-imaging printers • Data communication – Notebook computers – Desktop PCs – WinCE handheld products – Personal Digital Assistants – Printers – Auto PCs – Dongles – Set-top box • Digital imaging – Digital cameras – Photo-imaging printers • Telecommunication products – Mobile phones – Pagers • Electronic wallet • Small industrial and medical instrumentation – General data collection devices – Patient and pharmaceutical data collection devices • IR LANs • Miniature package – Height: 3.90 mm – Width: 9.80 mm – Depth: 4.65 mm • Guaranteed temperature performance, -25 to 70°C – Critical parameters are guaranteed over temperature and supply voltage • Low power consumption – Low shutdown current (10 nA typical) – Complete shutdown of TXD, RXD, and PIN diode • Withstands >100 mVp-p power supply ripple typically • VCC supply 2.7 to 5.25 volts • Integrated EMI shield • LED stuck-high protection • Designed to accommodate light loss with cosmetic windows • IEC 825-Class 1 eye safe • Interface to various super I/O and controller devices Functional Block Diagram Pinout VCC REAR VIEW CX2 VCC (6) CX1 GND (8) NC (7) 8 RECEIVER SHIELD RXD (4) TRANSMITTER TXD (3) LED C (2) VCC R1 LED A (1) Figure 1. HSDL-3603 functional block diagram. Ordering Information Part Number Packaging Type HSDL-3603-007 Tape and Reel Marking Information The unit is marked with 3603yyww on the shield. 3603 = Product name yy = year ww = work week 2 6 5 4 3 2 1 Figure 2. Rear view diagram with pin-out. SD/MODE (5) HSDL-3603 7 Package Front View Quantity 1800 Application Support Information The Application Engineering Group is available to assist you with the application designs associated with the HSDL-3603 infrared transceiver module. You can contact them through your local sales representatives for additional details. I/O Pins Configuration Table Pin 1 Symbol LED A Description LED Anode I/O Type Input 2 3 LED C TXD LED Cathode Transmit Data Output Input, Active High 4 RXD Receive Data Output, Active Low 5 SD/Mode Shutdown/ Mode Select Input, Active High 6 VCC 7 8 – NC GND Shield Supply Voltage No Connect Ground EMI Shield Supply Voltage No Connect Ground EMI Shield Function This pin can be connected directly to VCC (i.e., without series resistor) at less than 3 V. Please refer to Table 1 for VCC versus Series Resistor, R1. Leave this pin unconnected. This pin is used to transmit serial data when SD/Mode pin is low. If this pin is held high longer than ~100 µs, the LED would be turned off when used in conjunction with the SD/Mode pin. TXD is low at initialization. This pin is capable of driving a standard CMOS or TTL load. No external pull-up or pull-down resistor is required. It is in tri-state mode when the transceiver is in shutdown mode and during digital serial programming operations. RXD is high at initialization. The transceiver is in shutdown mode if this pin is high for more than 400 µs. On the falling edge of this signal, the state of the TXD pin sampled and used to set receiver low bandwidth (TXD=low) or high bandwidth (TXD=high) mode. See Figure 2 for bandwidth selection timings. SD is low at initialization. Regulated, 2.7 to 5.25 Volts. Connect to system ground. Connect to system ground via a low inductance trace. For best performance, do not connect directly to the transceiver pin GND. Recommended Application Circuit Components Component Recommended Value R1 0 Ω ± 5%, 0.5 Watt, for 2.7 V 1.8 Ω ± 5%, 0.5 Watt, for 3.0 V 4.7 Ω ± 5%, 0.5 Watt, for 3.3 V 6.8 Ω ± 5%, 0.5 Watt, for 3.5 V CX1 0.47 µF ± 20%, X7R Ceramic CX2 6.8 µF ± 20%, Tantalum Notes 1 2 Notes: 1. CX1 must be placed within 0.7 cm of the HSDL-3603 to obtain optimum noise immunity. 2. In environments with noisy power supplies, supply rejection performance can be enhanced by including CX2, as shown in Figure 1: ”HSDL-3603 Functional Block Diagram“ on Page 2. 3 Bandwidth Selection Timing The transceiver is in default SIR/ MIR mode when powered on. User needs to apply the following programming sequence to both the SD and TXD inputs to enable the transceiver to operate at FIR mode. VIH VIH 50% SD/MODE 50% SD/MODE VIL VIL tS tS tH tH VIH TXD 50% TXD 50% 50% VIL VIL Figure 3. Bandwidth selection timing at SIR/MIR mode. Figure 4. Bandwidth selection timing at FIR mode. Setting the transceiver to SIR/MIR Mode (9.6 kb/s to 1.152 Mbit/s) 1. Set SD/Mode input to logic HIGH 2. TXD input should remain at logic LOW 3. After waiting for tS ≥ 25 ns, set SD/Mode to logic LOW, the HIGH to LOW negative edge transition will determine the receiver bandwidth 4. Ensure that TXD input remains low for tH ≥ 100 ns, the receiver is now in SIR/MIR mode 5. SD input pulse width for mode selection should be > 50 ns. Setting the transceiver to FIR (4.0 Mbit/s) Mode 1. Set SD/Mode input to logic HIGH 2. After SD/Mode input remains HIGH at > 25ns, set TXD input to logic HIGH, wait tS ≥ 25 ns (from 50% of TXD rising edge till 50% of SD falling edge) 3. Then set SD/Mode to logic LOW, the HIGH to LOW negative edge transition will determine the receiver bandwidth 4. After waiting for tH ≥ 100ns, set the TXD input to logic LOW 5. SD input pulse width mode selection should be > 50ns. 4 50% Transceiver I/O Truth Table Inputs TXD Light Input to Receiver High Don’t Care Low High Low Low Don’t Care Don’t Care SD Low Low Low High Outputs LED On Off Off Off RXD Not Valid Low High High Notes 1, 2 Notes: 1. In-band IrDA signals and data rates ≤ 4Mbit/s. 2. RXD logic low is a pulsed response. The condition is maintained for a duration dependent on pattern and strength of the incident intensity. Caution: The BiCMOS inherent to the design of this component increases the component’s susceptibility to damage from electrostatic discharge (ESD). It is advised that normal static precautions be taken in handling and assembly of this component to prevent damage and/or degradation, which may be induced by ESD. 5 Absolute Maximum Ratings For implementations where case to ambient thermal resistance is ≤ 50°C/W. Parameter Symbol Min. Max. Storage Temperature TS –40 100 Operating Temperature TA –25 70 LED Anode Voltage VLEDA 0 6.5 Supply Voltage VCC 0 6.5 Input Voltage: TXD, SD/Mode VI 0 6.5 Output Voltage: RXD VO 0 6.5 DC LED Transmit Current ILED (DC) 150 Average Transmit Current ILED (PK) 650 Units °C °C V V V V mA mA Notes 3 Note: 3. ≤ 25% duty cycle, ≤ 90 µs pulse width. Recommended Operating Conditions Parameter Symbol Operating Temperature TA Supply Voltage VCC Logic Input Voltage Logic High VIH for TXD, SD/Mode Logic Low VIL Receiver Input Logic High EIH Irradiance Logic Low LED (Logic High) Current Pulse Amplitude Receiver Data Rate EIL ILEDA Min. Typ. –25 2.7 2/3 VCC 0 0.0036 Max. 70 5.25 VCC 1/3 VCC 500 Units °C V V V mW/cm2 Conditions 0.0090 500 mW/cm2 400 0.3 600 µW/cm2 mA 0.576 Mbit/s ≤ in-band signals ≤ 4 Mbit/s[4] For in-band signals ≤ 115.2 kbit/s[4] 0.0096 4.0 Mbit/s For in-band signals ≤ 115.2 kbit/s[4] Note: 4. An in-band optical signal is a pulse/sequence where the peak wavelength, λp, is defined as 850 ≤ λp ≤ 900 nm, and the pulse characteristics are compliant with the IrDA Serial Infrared Physical Layer Link Specification v1.4. 6 Electrical and Optical Specifications Specifications (Min. and Max. values) hold over the recommended operating conditions unless otherwise noted. Unspecified test conditions may be anywhere in their operating range. All typical values (Typ.) are at 25°C with VCC set to 3.0 V unless otherwise noted. Parameter Symbol Min. Typ. Max. Units Conditions Receiver Viewing Angle 2θ 30 ° Peak Sensitivity Wavelength λp 880 nm RXD Output Voltage Logic High VOH VCC – 0.2 VCC V IOH = –200 µA, EI ≤ 0.3 µW/cm2 Logic Low VOL 0 0.4 V IOL = 200 µA, EI ≥ 3.6 µW/cm2 RXD Pulse Width (SIR) tPW (SIR) 1 4.0 µs θ ≤ 15°, CL = 12 pF[5] RXD Pulse Width (MIR) tPW(MIR) 100 500 ns θ ≤ 15°, CL = 12 pF 6] RXD Pulse Width (FIR) tPW(FIR) 80 165 ns θ ≤ 15°, CL = 12 pF[7] RXD Rise and Fall Times tr, tf 25 ns CL =12 pF Receiver Latency Time tL 10 150 µs Receiver Wake Up Time trw 10 150 µs Transmitter Radiant Intensity IEH 100 180 mW/Sr ILEDA = 400 mA, θ ≤ 15°, VTXD ≥ VIH T = 25 °C Viewing Angle 2θ 30 60 ° Peak Wavelength λP 875 nm Spectral Line Half Width ∆λ 35 nm TXD Logic Levels High VIH 2/3 VCC VCC V Low VIL 0 1/3 VCC V TXD Input Current High IH 0.02 10 µA VI ≥ VIH Low IL –10 –0.02 10 µA 0 ≤ VI ≤ VIL LED Current On IVLED 400 600 mA VI(TXD) ≥ VIH Shutdown IVLED 20 1000 nA VI(SD) ≥ VIH, TA = 25°C TXD Pulse Width (SIR) tPW (SIR) 1.5 1.6 1.8 µs tPW (TXD) = 1.6 µs at 115.2 kbit/s TXD Pulse Width (MIR) tPW(MIR) 148 217 260 ns tPW (TXD) = 217 ns at 1.152 Mbit/s TXD Pulse Width (FIR) tPW(FIR) 115 125 135 ns tPW (TXD) = 125 ns at 4.0 Mbit/s Maximum Optical PW tPW(max.) 60 100 µs TXD Rise and Fall Time (Optical) tr, tf 40 ns tPW (TXD) = 125 ns at 4.0 Mbit/s Transceiver Supply Current Shutdown ICC1 10 1000 nA VSD ≥ 2/3 VCC, TA = 25°C Idle ICC2 1.8 3.0 mA VI(TXD) ≤ VIL, EI = 0 Active ICC3 2.5 mA EI = 10 mW/cm2 Notes: 5. For in-band signals ≤ 115.2 kbit/s where 3.6 µW/cm2 ≤ EI ≤ 500 mW/cm2. 6. For in-band signals at 1.152 Mbit/s where 9.0 µW/cm2 ≤ EI ≤ 500 mW/cm2. 7. For in-band signals of 125 ns pulse width, 4 Mbit/s, 4 PPM at recommended 400 mA drive current. 7 390 RADIANT INTENSITY (mW/Sr) vs. ILED TA = 25°C, VCC = 3.0 V, ON-AXIS 2.80 370 350 330 2.70 2.60 VLED_A (V) 310 290 270 IEH (mW/Sr) VLED_A vs. ILED TA = 25°C, VCC = 3.0 V 250 230 210 2.50 2.40 2.30 2.20 190 2.10 170 150 250 300 350 400 450 500 550 600 650 2.00 250 300 350 400 450 500 550 600 650 ILED (mA) ILED (mA) Figure 5. IR LOP vs. ILED. Figure 6. IR VLED vs. ILED. tpw tpw VOH VOL LED ON 90% 90% 50% 50% 10% 10% LED OFF tf tr Figure 7. RXD output waveform. tr Figure 8. LED optical waveform. TXD LED tpw (MAX.) Figure 9. TXD ‘stuck on’ waveform. SD SD RX LIGHT TXD RXD TX LIGHT tRW Figure 10. Receiver wakeup time waveform. 8 tTW Figure 11. TXD wakeup time waveform. tf HSDL-3603 Package Outline Dimensions 4.90 MOUNTING CENTER 1.00 EMITTING CENTER LIGHT RECEIVING CENTER 9.80 93° ± 1° 3.90 0.1 8 –0.10 +0.20 7 6 5 4 3 0.37 2 1 0.65 0.83 3.5 P1.0 x 7 = 7 1 LEDA 5 SD/MODE 2 LEDC 6 Vcc 3 TXD 7 NC 4 RXD 8 GND 1.70 4.10 4.65 3.85 0.95 0.75 0.25 UNIT: mm TOLERANCE: ± 0.2 mm Figure 12. Package outline dimensions. 9 HSDL-3603 Tape and Reel Dimensions 4.00 ± 0.10 5°(MAX.) 1.75 ± 0.10 0.75 ± 0.10 1.55 ± 0.05 POLARITY PIN 8: GND +0.10 3.46 0 7.50 ± 0.10 16.00 ± 0.30 9.50 ± 0.10 +0.10 3.30 0 PIN 1: LED A 8.00 ± 0.10 2.46 ± 0.10 0.30 ± 0.10 4.50 ± 0.10 5°(MAX.) MATERIAL OF CARRIER TAPE: CONDUCTIVE POLYSTYRENE MATERIAL OF COVER TAPE: PVC 4.65 ± 0.10 METHOD OF COVER: HEAT ACTIVATED ADHESIVE 5.15 ± 0.10 PROGRESSIVE DIRECTION EMPTY (40 mm MIN.) LEADER PARTS MOUNTED (40 mm MIN.) EMPTY (40 mm MIN.) "B" "C" 330 QUANTITY 80 1800 UNIT: mm DETAIL A 2.0 ± 0.5 DIA. 13.0 ± 0.5 B C R 1.0 LABEL 16.40 + 2.00 0 21 ± 0.8 DETAIL A Figure 13. Tape and reel dimensions. 10 2.00 ± 0.50 Moisture Proof Packaging All HSDL-3603 options are shipped in moisture proof package. Once opened, moisture absorption begins. This part is compliant to JEDEC level 4. UNITS IN A SEALED MOISTURE-PROOF PACKAGE PACKAGE IS OPENED (UNSEALED) ENVIRONMENT LESS THAN 30°C, AND LESS THAN 60% RH YES NO BAKING IS NECESSARY PACKAGE IS OPENED LESS THAN 72 HOURS YES NO PERFORM RECOMMENDED BAKING CONDITIONS NO Figure 14. Baking conditions. Baking Conditions If the parts are not stored in dry conditions, they must be baked before reflow to prevent damage to the parts. Package In Reels In Bulk Temperature 60˚C 100˚C 125˚C 150˚C Baking should only be done once. 11 Time ≥ 48 hours ≥ 4 hours ≥ 2 hours ≥ 1 hour Recommended Storage Conditions Storage 10°C to 30°C Temperature Relative Humidity below 60% RH Time from Unsealing to Soldering After removal from the bag, the parts should be soldered within three days if stored at the recommended storage conditions. If times longer than two days are needed, the parts must be stored in a dry box. In process zone P1, the PC board and HSDL-3603 castellation I/O pins are heated to a temperature of 125°C to activate the flux in the solder paste. The temperature ramp up rate, R1, is limited to 4°C per second to allow for even heating of both the PC board and HSDL-3603 castellation I/O pins. Process zone P2 should be of sufficient time duration (> 60 seconds) to dry the solder paste. The temperature is raised to a level just below the liquidus point of the solder, usually 170°C (338°F). Process zone P3 is the solder reflow zone. In zone P3, the temperature is quickly raised above the liquidus point of solder to 230°C (446°F) for optimum results. The dwell time above the liquidus point of solder should be between 15 and 90 seconds. It usually takes about 15 seconds to assure proper coalescing of the solder balls into liquid solder and the formation of good solder 12 MAX. 245°C 230 T – TEMPERATURE – (°C) Reflow Profile The reflow profile is a straightline representation of a nominal temperature profile for a convective reflow solder process. The temperature profile is divided into four process zones, each with different ∆T/∆time temperature change rates. The ∆T/∆time rates are detailed in the following table. The temperatures are measured at the component to printed circuit board connections. R3 200 183 170 150 R2 90 sec. MAX. ABOVE 183°C 125 R1 100 R4 R5 50 25 0 50 100 150 200 250 300 t-TIME (SECONDS) P1 HEAT UP P2 SOLDER PASTE DRY P3 SOLDER REFLOW P4 COOL DOWN Figure 15. Reflow graph. Process Zone Heat Up Solder Paste Dry Solder Reflow Cool Down Symbol P1, R1 P2, R2 P3, R3 P3, R4 P4, R5 ∆T 25˚C to 125˚C 125˚C to 170˚C 170˚C to 230˚C (245˚C max.) 230˚C to 170˚C 170˚C to 25˚C connections. Beyond a dwell time of 90 seconds, the intermetallic growth within the solder connections becomes excessive, resulting in the formation of weak and unreliable connections. The temperature is then rapidly reduced to a point below the solidus temperature of the solder, usually 170°C (338°F), to allow the solder within the connections to freeze solid. Maximum ∆T/∆time 4˚C/s 0.5˚C/s 4˚C/s –4˚C/s –3˚C/s Process zone P4 is the cool down after solder freeze. The cool down rate, R5, from the liquidus point of the solder to 25°C (77°F) should not exceed -3°C per second maximum. This limitation is necessary to allow the PC board and HSDL-3603 castellation I/O pins to change dimensions evenly, putting minimal stresses on the HSDL-3603 transceiver. Appendix A: HSDL-3603 SMT Assembly Application Note 1.0. Solder Pad, Mask, and Metal Solder Stencil Aperture METAL STENCIL FOR SOLDER PASTE PRINTING STENCIL APERTURE LAND PATTERN SOLDER MASK PCBA Figure 16. Stencil and PCBA. 1.1. Recommended Land Pattern for HSDL-3603 Dimension a b c (pitch) d e f g mm 2.00 0.70 1.00 2.50 1.51 3.09 2.84 RX LENS inches 0.079 0.028 0.039 0.098 0.059 0.122 0.112 TX LENS e d SHIELD'S SOLDER PAD g f a FIDUCIAL b 8x SOLDER PAD Figure 17. Top view of land pattern. 13 c 1.2. Adjacent Land Keep-out and Solder Mask Areas Dimension h j k l mm min. 0.2 10.8 5.1 3.2 inches min. 0.008 0.425 0.201 0.126 • Adjacent land keep-out is the maximum space occupied by the unit relative to the land pattern. There should be no other SMD components within this area. • “h” is the minimum solder resist strip width required to avoid solder bridging adjacent pads. • It is recommended that 2 fiducial cross be placed at mid-length of the pads for unit alignment. Note: Wet/Liquid photoimagineable solder resist/mask is recommended. 14 j Rx LENS LAND Tx LENS SOLDER MASK h k Y CENTER l Figure 18. PCBA – Adjacent land keep-out and solder mask. 1.3. Recommended Metal Solder Stencil Aperture It is recommended that only 0.152 mm (0.006 inches) or 0.127 mm (0.005 inches) thick stencil be used for solder paste printing. This is to ensure adequate printed solder paste volume and no shorting. The following combination of metal stencil aperture and metal stencil thickness should be used: See Figure 18 t, nominal stencil thickness l, length of aperture mm inches mm inches 0.152 0.006 2.0 ± 0.05 0.12 ± 0.002 0.127 0.005 2.0 ± 0.05 0.15 ± 0.002 w, the width of aperture is fixed at 0.70 mm (0.027 inches) Aperture opening for shield pad is 2.50 mm x 1.51 mm as per land dimension. APERTURES AS PER LAND DIMENSIONS t (STENCIL THICKNESS) SOLDER PASTE METAL STENCIL w l Figure 19. Solder paste stencil aperture. 15 Appendix B: PCB Layout Suggestion The following PCB layout guidelines should be followed to obtain a good PSRR and EM immunity, resulting in good electrical performance. Things to note: Refer to the diagram below for an example of a 4-layer board. TOP LAYER CONNECT THE METAL SHIELD AND MODULE GROUND PIN TO BOTTOM GROUND LAYER. 1. The AGND pin should be connected to the ground plane. LAYER 2 CRITICAL GROUND PLANE ZONE. DO NOT CONNECT DIRECTLY TO THE MODULE GROUND PIN. 2. C1 and C2 are optional supply filter capacitors; they may be left out if a clean power supply is used. 3. VLED can be connected to either unfiltered or unregulated power supply. If VLED and VCC share the same power supply and C1 is used, the connection should be before the current limiting resistor R1. In a noisy environment, including capacitor C2 can enhance supply rejection. C1 is generally a ceramic capacitor of low inductance providing a wide frequency response while C2 is a tantalum capacitor of big volume and fast frequency response. The use of a tantalum capacitor is more critical on the VLED line, which carries a high current. LAYER 3 KEEP DATA BUS AWAY FROM CRITICAL GROUND PLANE ZONE. BOTTOM LAYER (GND) The area underneath the module at the second layer, and 3 cm in all directions around the module, is defined as the critical ground plane zone. The ground plane should be maximized in this zone. Refer to application note AN1114 or the Agilent IrDA Data Link Design Guide for details. The layout below is based on a 2-layer PCB. 17.2 mm 4. Preferably, a multi-layered board should be used to provide sufficient ground plane. Use the layer underneath and near the transceiver module as VCC, and sandwich that layer between ground connected board layers. 28 mm Top Layer Figure 20. PCB layout suggestion. 16 Bottom Layer Appendix C: General Application Guide for the HSDL-3603 Infrared IrDA® Compliant 4 Mb/s Transceiver Description The HSDL-3603 wide voltage operating range infrared transceiver is a low-cost and small form factor that is designed to address the mobile computing market such as notebooks, printers, and LAN access as well as small embedded mobile products such as digital cameras, cellular phones, and PDAs. It is fully compliant to IrDA 1.4 specification up to 4 Mb/s. The design of the HSDL-3603 also includes the following unique features: • Low passive component count. • Shutdown mode for low power consumption requirement. • Single-receive output for all data rates. 17 Selection of Resistor R1 Resistor R1 should be selected to provide the appropriate peak pulse LED current over different ranges of VCC . The recommended selection of R1 is tabulated in the table on page 3. The HSDL-3603 typically provides 180 mW/Sr of intensity at the recommended minimum peak pulse LED current of 400 mA. Interface to Recommended I/O chips The HSDL-3603’s TXD data input is buffered to allow for CMOS drive levels. No peaking circuit or capacitor is required. Data rate from 9.6 kb/s up to 4 Mb/s is available at the RXD pin. Following shows the interface of HSDL-3603 with National Semiconductor’s Super I/Os, and the SMC I/O chips. (A) National Semiconductor Super I/O and Infrared Controller For National Semiconductor Super I/O and Infrared Controller chips, IR link can be realized with the following connections: • Connect IRTX of the National Super I/O or IR Controller to TXD (pin 3) of the HSDL-3603. • Connect IRRX1 of the National Super I/O or IR Controller to RXD (pin 4) of the HSDL-3603. • Connect IRSL0 of the National Super I/O or IR Controller to SD/Mode (pin 5) of the HSDL3603. Please refer to the table below for the IR pin assignments for the National Super I/O and IR Controllers that support IrDA 1.4 up to 4 Mb/s: PC87391/2/3/3F-VJG PC97338VJG PC87360/3/4/5/6 PC87309VLJ PC8(9)7307 PC8(9)7317VUL IRTX 70 63 57 44 81 81 R1 LEDC (2) LEDA (1) TXD (3) SP IRTX IRRX1 HSDL-3603 RXD (4) IRSL0 SD/MODE (5) CX1 VCC (6) GND (8) CX2 VCC HSDL-3603 FUNCTIONAL BLOCK DIAGRAM Figure 21. NS Super I/O configuration circuit. 18 IRSL0 68 66 58 100 79 79 Please refer to the National Semiconductor data sheets and application notes for updated information. VCC NATIONAL SEMICONDUCTOR SUPER I/O or IR CONTROLLER IRRX1 69 65 59 43 80 80 (B) Standard Micro System Corporation (SMC) Super and Ultra I/O Controllers For SMC Super and Ultra I/O Controller chips, IR link can be realized with the following connections: Please refer to the table below for the IR pin assignments for the SMC Super or Ultra I/O Controllers that support IrDA 1.4 up to 4 Mb/s: • Connect IRTX of the SMC Super or Ultra I/O Controller to TXD (pin 3) of the HSDL-3603. • Connect IRRX of the SMC Super or Ultra I/O Controller to RXD (pin 4) of the HSDL-3603. • Connect IRMODE of the Super or Ultra I/O Controller to SD/Mode (pin 5) of the HSDL3603. FDC37C669FR FDC37N769 FDC37C957/8FR IRTX 89 87 204 VCC R1 LEDC (2) IRRX STANDARD MICROSYSTEM CORPORATION SUPER I/O or IR CONTROLLER IRMODE LEDA (1) RXD (4) SD/MODE (5) HSDL-3603 IRTX TXD (3) SP CX1 GND (8) VCC (6) CX2 VCC GND Figure 22. SMC Super I/O configuration circuit. 19 IRRX 88 86 203 IRMODE 23 21 145 or 190 (C) Mobile Phone and PDA Platform The block diagrams below show how the IrDA port fits into a mobile phone and PDA platform. MICROPHONE AUDIO INTERFACE SPEAKER DSP CORE ASIC CONTROLLER RF INTERFACE TRANSCEIVER MOD/ DE-MODULATOR IR MICROCONTROLLER USER INTERFACE Figure 23. IR layout in mobile phone platform. LCD PANEL RAM IR CPU FOR EMBEDDED APPLICATION ROM PCMCIA CONTROLLER TOUCH PANEL RS232C DRIVER Figure 24. IR layout in PDA platform. 20 COM PORT Appendix D: Window Design In the figure below, X is the width of the window, Y is the height of the window and Z is the distance from the HSDL-3603 to the back of the window. The distance from the center of the LED lens to the center of the photodiode lens, K, is 7.08 mm. The equations for computing the window dimensions are as follows: Optical Port Dimensions for HSDL3603: To ensure IrDA compliance, some constraints on the height and width of the window exist. The minimum dimensions ensure that the IrDA cone angles are met without vignetting. The maximum dimensions minimize the effects of stray light. The minimum size corresponds to a cone angle of 30° and the maximum size corresponds to a cone angle of 60º. X = K + 2*(Z + D)*tanA Y = 2*(Z + D)*tanA The above equations assume that the thickness of the window is negligible compared to the distance of the module from the back OPAQUE MATERIAL IR TRANSPARENT WINDOW Y X IR TRANSPARENT WINDOW K Z A D Figure 25. Window design diagram. 21 OPAQUE MATERIAL of the window (Z). If they are comparable, Z' replaces Z in the above equation. Z' is defined as Z' = Z + t/n where ‘t’ is the thickness of the window and ‘n’ is the refractive index of the window material. The depth of the LED image inside the HSDL-3603, D, is 8 mm. ‘A’ is the required half angle for viewing. For IrDA compliance, the minimum is 15° and the maximum is 30°. Assuming the thickness of the window to be negligible, the equations result in the following tables and graphs: APERTURE WIDTH (X) vs. MODULE DEPTH APERTURE HEIGHT (Y) vs. MODULE DEPTH 30 25 25 20 15 10 X MAX. X MIN. 5 0 0 1 2 3 4 5 6 7 8 9 MODULE DEPTH (Z) – mm Figure 26. Aperture width (X) vs. module depth. 22 Aperture Height (y, mm) max. min. 9.238 4.287 10.392 4.823 11.547 5.359 12.702 5.895 13.856 6.431 15.011 6.967 16.166 7.503 17.321 8.038 18.475 8.574 19.630 9.110 APERTURE HEIGHT (Y) – mm APERTURE WIDTH (X) – mm Module Depth, (z) mm 0 1 2 3 4 5 6 7 8 9 Aperture Width (x, mm) max. min. 16.318 11.367 17.472 11.903 18.627 12.439 19.782 12.975 20.936 13.511 22.091 14.047 23.246 14.583 24.401 15.118 25.555 15.654 26.710 16.190 20 15 10 5 0 Y MAX. Y MIN. 0 1 2 3 4 5 6 7 8 9 MODULE DEPTH (Z) – mm Figure 27. Aperture height (Y) vs. module depth. Window Material Almost any plastic material will work as a window material. Polycarbonate is recommended. The surface finish of the plastic should be smooth, without any texture. An IR filter dye may be used in the window to make it look black to the eye, but the total optical loss of the window should be 10% or less for best optical performance. Light loss should be measured at 875 nm. The recommended plastic materials for use as a cosmetic window are available from General Electric Plastics. Shape of the Window From an optics standpoint, the window should be flat. This ensures that the window will not alter either the radiation pattern of the LED, or the receive pattern of the photodiode. If the window must be curved for mechanical or industrial design reasons, place the same curve on the back side of the window that has an identical radius as the front side. While this will not completely eliminate the lens effect of the front curved surface, it will significantly reduce the effects. The amount of change in the radiation pattern is dependent upon the material chosen for the window, the radius of the front and back curves, and the distance from the back surface to the transceiver. Once these items are known, a lens design can be made which will eliminate the effect of the front surface curve. The following drawings show the effects of a curved window on the radiation pattern. In all cases, the center thickness of the window is 1.5 mm, the window is made of polycarbonate plastic, and the distance from the transceiver to the back surface of the window is 3 mm. Recommended Plastic Materials: Material Number Lexan 141L Lexan 920A Lexan 940A Light Transmission 88% 85% 85% Haze 1% 1% 1% Refractive Index 1.586 1.586 1.586 Note: 920A and 940A are more flame retardant than 141L. Recommended Dye: Violet #21051 (IR transmissant above 625 nm). Flat Window (First Choice) Figure 28. Window design choices. 23 Curved Front and Back (Second Choice) Curved Front, Flat Back (Do Not Use) www.agilent.com/semiconductors For product information and a complete list of distributors, please go to our web site. For technical assistance call: Americas/Canada: +1 (800) 235-0312 or (408) 654-8675 Europe: +49 (0) 6441 92460 China: 10800 650 0017 Hong Kong: (+65) 6271 2451 India, Australia, New Zealand: (+65) 6271 2394 Japan: (+81 3) 3335-8152(Domestic/International), or 0120-61-1280(Domestic Only) Korea: (+65) 6271 2194 Malaysia, Singapore: (+65) 6271 2054 Taiwan: (+65) 6271 2654 Data subject to change. Copyright © 2002 Agilent Technologies, Inc. December 3, 2002 5988-7926EN