SP504MCM-L

SP504 61 SD(a) 62 VCC 63 TT(a) 64 GND 65 TT(b) 66 CS(a) 67 CS(b) 69 DM(b) 70 RD(a) 68 DM(a) 71 RD(b) 72 GND 73 VCC 74 VCC 75 GND 76 SCT(a) 77 SCT(b) 78 DSR 79 SCT RxD 1 60 GND RDEC0 2 59 SD(b) RDEC1 3 58 TR(a) RDEC2 4 57 GND RDEC3 5 56 TR(b) TTEN 6 55 VCC SCTEN 7 54 RS(a) N/C 8 53 GND SP504 TDEC3 9 TDEC2 10 TDEC1 11 52 RS(b) 51 LL(a) 50 GND TDEC0 12 49 LL(b) IC(b) 40 IC(a) 39 RT(b) 38 RT(a) 37 RR(b) 36 RR(a) 35 GND 34 VCC 33 C2- 31 C2+ 28 VSS 32 41 VCC C1- 30 42 ST(a) RxC 20 GND 29 43 GND DCD 19 V DD 27 44 ST(b) V35_STAT 18 C1+ 26 45 RL(b) RL 17 VCC 25 46 GND RTS 16 LL 24 47 RL(a) TxC 15 RI 21 48 VCC TxD 14 ST 22 DTR 13 STEN 23 • +5V Only • Seven (7) Drivers and Seven (7) Receivers • Driver and Receiver Tri-State Control • Reduced V.35 Termination Network • Pin Compatible with the SP503 • Software Selectable Interface Modes: -RS-232E (V.28) -RS-422A (V.11, X.21) -RS-449 (V.11 & V.10) -RS-485 -V.35 -EIA-530 (V.11 & V.10) -EIA-530A (V.11 & V.10) -V.36 80 CTS WAN Multi-Mode Serial Transceiver DESCRIPTION The SP504 is a single chip device that supports eight (8) physical serial interface standards for Wide Area Network connectivity. The SP504 is fabricated using a low power BiCMOS process technology, and incorporates an Exar patented (5,306,954) charge pump allowing +5V only operation. Seven (7) drivers and seven (7) receivers can be configured via software for any of the above interface modes at any time. The SP504 is suitable for DTE-DCE applications. The SP504 requires only one external resistor per V.35 driver for compliant V.35 Operation. Vcc SWITCHABLE V.35 TERMINATION RESISTOR NETWORKS 22µF, 16V 22µF, 16V RxD Vdd C1C2+ Programmable Charge Pump RxD TxD RxC CTS CTS DSR DSR DCD DCD RI 22µF, 16V Vss C2- RxC SCT 22µF, 16V C1+ SP504 DTR DTR RTS RTS RL RL LL LL ST ST TT TT RI SCT Receiver Decode TxD Driver Decode Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com  SP504_102_121708 ABSOLUTE MAXIMUM RATINGS STORAGE CONSIDERATIONS These are stress ratings only and functional operation of the device at these ratings or any other above those indicated in the operation sections of the specifications below is not implied. Exposure to absolute maximum rating conditions for extended periods of time may affect reliability. Due to the relatively large package size of the 80-pin quad flat-pack, storage in a low humidity environment is preferred. Large high density plastic packages are moisture sensitive and should be stored in Dry Vapor Barrier Bags. Prior to usage, the parts should remain bagged and stored below 40°C and 60%RH. If the parts are removed from the bag, they should be used within 48 hours or stored in an environment at or below 20%RH. If the above conditions cannot be followed, the parts should be baked for four hours at 125°C in order remove moisture prior to soldering. Exar ships the 80-pin QFP in Dry Vapor Barrier Bags with a humidity indicator card and desiccant pack.The humidity indicator should be below 30%RH. VCC.......................................................................+7V Input Voltages: Logic...........................-0.3V to (VCC+0.5V) Drivers........................-0.3V to (VCC+0.5V) Receivers..........................................±15V Output Voltages: Logic...........................-0.3V to (VCC+0.5V) Drivers...............................................±14V Receivers....................-0.3V to (VCC+0.5V) Storage Temperature.......................-65˚C to +150˚C Power Dissipation.......................................2000mW Package Derating: øJA................................................46 °C/W øJC................................................16 °C/W SPECIFICATIONS TA = +25°C and VCC = +5.0V unless otherwise noted. PARAMETER MIN. TYP. MAX. UNITS 0.8 Volts CONDITIONS Logic Inputs VIL VIH 2.0 Volts LOGIC OUTPUTS VOL 0.4 VOH 2.4 Volts IOUT = +3.2mA Volts IOUT = -1.0mA RS-485 DRIVER TTL Input Levels VIL 0.8 VIH 2.0 Volts Volts Outputs HIGH Level Output +6.0 LOW Level Output -0.3 Differential Output +/-1.5 Balance Offset Volts +/-5.0 Volts RL = 54Ω, CL = 50pF +/-0.2 Volts |VT| - |VT| +2.5 Volts Open Circuit Voltage Output Current +/-6.0 28.0 Short-Circuit Current +/-250 Transition Time 20 Max. Transmission Rate 10 Propagation Delay tPHL 50 Volts 40 Volts mA RL = 54Ω mA Terminated in -7V to +10V ns Rise/Fall time, 10% to 90% Mbps 80 100 ns RL = 54Ω; Figure 3a TA @ 25°C and VCC = +5V only Figures 3a and 5; RL= 54Ω, CL=50pF Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com  SP504_102_121708 SPECIFICATIONS TA = +25°C and VCC = +5.0V unless otherwise noted. PARAMETER MIN. TYP. MAX. UNITS CONDITIONS 50 80 100 ns TA @ 25°C and VCC = +5V only Figures 3a and 5; RL= 54Ω, CL=50pF 20 40 ns |tPHL - tPLH|; TA @ 25°C 0.4 Volts RS-485 DRIVER (continued) Propagation Delay tPLH Differential Driver Skew RS-485 RECEIVER TTL Output Levels VOL VOH 2.4 Volts Input HIGH Threshold +0.2 +12 Volts (a)-(b) LOW Threshold -7.0 -0.2 Volts (a)-(b) Common Mode Range -7.0 +12 Volts HIGH Input Current Refer to Receiver input graph LOW Input Current Refer to Receiver input graph Receiver Sensitivity +/-0.2 Volts Input Impedance 12 kΩ Max. Transmission Rate 10 Mbps Propagation Delay tPHL 80 110 180 ns Propagation Delay tPLH 80 110 180 ns Differential Receiver Skew 30 ns Over -7V to +12V common mode Range Figure 3a TA @ 25°C and VCC = +5V only. Figures 3a and 7; A is inverting and B is non-inverting. |tPHL - tPLH|; TA @ +25°C V.35 DRIVER TTL Input Levels VIL 0.8 VIH Outputs 2.0 Volts Volts All Outputs measured with 150Ω termination resistor connected to the non-inverting outputs as shown in Figure 19. Differential Output +/-0.44 +/-0.66 Volts Source Impedance 50 100 150 Ω Short-Circuit Impedance 135 150 165 Ω Voltage Output Offset -0.6 Transition Time +0.6 Volts 35 60 ns Max. Transmission Rate 10 Propagation Delay tPHL 50 80 100 ns Propagation Delay tPLH 50 80 100 ns 30 40 ns 0.4 Volts DIfferential Driver Skew Mbps RL = 100Ω VOUT = -2V to +2V; A = B 48kbps data rate; TA @ 25°C RL = 100Ω TA @ 25°C and VCC = +5V only Figures 3b and 5 |tPHL - tPLH|; TA @ +25°C V.35 RECEIVER TTL Output Levels VOL VOH 2.4 Volts Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com  SP504_102_121708 SPECIFICATIONS TA = +25°C and VCC = +5.0V unless otherwise noted. PARAMETER MIN. TYP. MAX. UNITS CONDITIONS V.35 RECEIVER (continued) Input Differential Threshold +/-80 mV Input Impedance 90 100 110 Ω Short-Circuit Impedance 135 150 165 Ω Max. Transmission Rate 10 Propagation Delay tPHL 100 130 200 ns Propagation Delay tPLH 100 130 200 ns DIfferential Receiver Skew VIN = +2V to -2V Mbps 30 ns TA @ 25°C and VCC = +5V only Figures 3b and 7; A is inverting and B is non-inverting. |tPHL - tPLH|; TA @ 25°C RS-422 DRIVER (V.11) TTL Input Levels VIL 0.8 VIH 2.0 Volts Volts Outputs Open circuit Voltage, VO Differential Output, VT +/-6.0 Volts RL = 3.9kΩ +/-2.0 +/-5.0 Volts RL = 100Ω 0.5VO 0.67VO Volts TA @ 25°C +/-0.4 Volts |VT| - |VT| Balance Offset Short Circuit Current Power Off Current Transition Time +3.0 Volts +/-150 mA VOUT = 0V +/-100 µA VCC = 0V, VOUT = +/-0.25V 20 40 ns Rise/Fall time, 10% - 90% Max. Transmission Rate 10 Propagation Delay tPHL 50 80 100 ns Propagation Delay tPLH 50 80 100 ns TA @ 25°C and VCC = +5V only Figures 3a and 5; RDIFF = 100Ω 20 40 ns |tPHL - tPLH|; TA @ 25°C 0.4 Volts Differential Skew Mbps RL = 100Ω; Figure 3a RS-422 RECEIVER (V.11) TTL Output Levels VOL VOH 2.4 Volts Input HIGH Threshold +0.2 +6.0 Volts (a)-(b) LOW Threshold -6.0 -0.2 Volts (a)-(b) Common Mode Range -7.0 +7 Volts HIGH Input Current Refer to Receiver input graph LOW Input Current Refer to Receiver input graph Receiver Sensitivity +/-0.3 Volts VCM = +7V to -7V VIN = +10V to -10V Input Impedance 4 kΩ Max. Transmission Rate 10 Mbps Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com  SP504_102_121708 SPECIFICATIONS TA = +25°C and VCC = +5.0V unless otherwise noted. PARAMETER MIN. TYP. MAX. UNITS CONDITIONS RS-422 RECEIVER (V.11) (continued) Propagation Delay tPHL 80 110 180 ns Propagation Delay tPLH 80 110 180 ns DIfferential Receiver Skew 30 ns TA @ 25°C and VCC = +5V only. Figures 3b and 7; A is inverting and B is non-inverting. |tPHL - tPLH|; TA @ 25°C RS-232 DRIVER (V.28) TTL Input Levels VIL 0.8 VIH 2.0 Volts Volts Outputs HIGH Level Output +5.0 +15.0 Volts RL = 3kΩ, VIN = 0.8V LOW Level Output -15.0 -5.0 Volts RL = 3kΩ, VIN = 2.0V -15 +15 Volts +/-100 mA Open Circuit Voltage Short Circuit Current Power Off Impedance 300 Ω Slew Rate Transistion Time VOUT = 0V VCC = 0V, VOUT = +/-2.0V 30 V/µs RL = 3kΩ, CL = 50pF; VCC = +5.0V, TA @ 25°C 1.56 µs RL = 3KΩ, CL = 2500pF; between +/-3V, TA @ +25°C Max. Transmission Rate 120 230.4 kbps Propagation Delay tPHL 0.5 1 4 µs Propagation Delay tPLH 0.5 1 4 µs 0.4 Volts RL = 3kΩ, CL = 2500pF TA @ 25°C and VCC = +5V only. Measured from 1.5V of VIN to 50% of VOUT; RL = 3kΩ RS-232 RECEIVER (V.28) TTL Output Levels VOL VOH 2.4 Volts Input HIGH Threshold 1.7 LOW Threshold 0.8 3.0 1.2 Volts Reciever Open Circuit Bias Input Impedance Volts +2.0 7 Volts 3 5 Max. Transmission Rate 120 230.4 kΩ Propagation Delay tPHL 0.05 0.25 1 µs Propagation Delay tPLH 0.05 0.25 1 µs 0.8 Volts VIN = +15V to -15V kbps TA @ 25°C and VCC = +5V only. Measured from 50% of VIN to 1.5V of VOUT RS-423 DRIVER (V.10) TTL Input Levels VIL VIH 2.0 Volts Outputs Open Circuit Voltage, VO +/-4.0 +/-6.0 Volts RL = 3.9kΩ Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com  SP504_102_121708 SPECIFICATIONS TA = +25°C and VCC = +5.0V unless otherwise noted. PARAMETER MIN. TYP. MAX. UNITS CONDITIONS +3.6 +6.0 Volts RL = 450Ω; VOUT ≥0.9VOC -6.0 -3.6 Volts RL = 450Ω; VOUT ≥0.9VOC Volts TA = +25°C, VCC = +5.0V RS-423 DRIVER (V.10) (continued) HIGH Level Output, VT LOW Level Output, VT 0.9VOC Short Circuit Current +/-150 mA VOUT = 0V, VCC = +5.0V Power Off Current +/-100 µA VCC = 0V, VOUT = +/-0.25V ns Rise/Fall time, between +/-3V Transition Time 100 Max. Transmission Rate 120 kbps Propagation Delay tPHL 0.05 0.5 2 µs Propagation Delay tPLH 0.05 0.5 2 µs 0.4 Volts RL = 450Ω TA @ 25°C and VCC = +5V only. Measured from 1.5V of VIN to 50% of VOUT; RL = 450Ω RS-423 RECEIVER (V.10) TTL Output Levels VOL VOH 2.4 Volts Input HIGH Threshold +0.3 +7.0 Volts LOW Threshold -7.0 -0.3 Volts HIGH Input Current Refer to Receiver input graph LOW Input Current Refer to Receiver input graph Receiver Sensitivity +/-0.3 Input Impedance 4 Volts VCM = +7V to -7V kΩ VIN = +10V to -10V Max. Transmission Rate 120 Propagation Delay tPHL 0.05 0.2 1 kbps µs Propagation Delay tPLH 0.05 0.2 1 µs 4.75 5.00 5.25 Volts TA @ 25°C and VCC = +5V only Measured from 50% of VIN to 1.5V of VOUT POWER REQUIREMENTS VCC ICC (No Mode Selected) 30 mA All ICC values are with VCC = +5V ICC (RS-232 Mode) 140 mA fIN = 120kbps; Drivers loaded ICC (RS-422 Mode) 320 mA fIN = 2Mbps; Drivers loaded ICC (RS-449 Mode) 320 mA fIN = 2Mbps; Drivers loaded ICC (EIA-530 Mode) 320 mA fIN = 2Mbps Drivers loaded ICC (EIA-530A Mode) 320 mA fIN = 2Mbps Drivers loaded ICC (RS-485 Mode) 370 mA fIN = 2Mbps Drivers loaded ICC (V.35 Mode) 210 mA fIN = 2Mbps Drivers loaded ICC (V.36 Mode) 310 mA fIN = 2Mbps Drivers loaded ENVIRONMENTAL AND MECHANICAL Operating Temperature Range Storage Temperature Range ESD 0 -65 500 +70 °C +150 °C V HBM Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com  SP504_102_121708 RECEIVER INPUT GRAPHS RS-423 RECEIVER RS-422 RECEIVER +3.25mA +3.25mA -10V -10V -3V +3V -3V +3V +10V +10V Maximum Input Current Versus Voltage Maximum Input Current Versus Voltage -3.25mA -3.25mA RS-485 RECEIVER +1.0mA -7V -3V +6V +12V 1 Unit Load Maximum Input Current Versus Voltage -0.6mA OTHER AC CHARACTERISTICS TA = +70°C to 0°C and VCC = +4.75V to +5.25V unless otherwise noted. PARAMETER MIN. TYP. MAX. UNITS CONDITIONS DRIVER DELAY TIME BETWEEN ACTIVE MODE AND TRI-STATE MODE RS-232 Mode tPZL; Tri-state to Output LOW 0.70 5.0 µs CL = 100pF, Fig. 4 ; S1 closed tPZH; Tri-state to Output HIGH 0.40 2.0 µs CL = 100pF, Fig. 4 ; S2 closed tPLZ; Output LOW to Tri-state 0.20 2.0 µs CL = 100pF, Fig. 4 ; S1 closed tPHZ; Output HIGH to Tri-state 0.40 2.0 µs CL = 100pF, Fig. 4 ; S2 closed tPZL; Tri-state to Output LOW 0.15 2.0 µs CL = 100pF, Fig. 4 ; S1 closed tPZH; Tri-state to Output HIGH 0.20 2.0 µs CL = 100pF, Fig. 4 ; S2 closed tPLZ; Output LOW to Tri-state 0.20 2.0 µs CL = 100pF, Fig. 4 ; S1 closed tPHZ; Output HIGH to Tri-state 0.15 2.0 µs CL = 100pF, Fig. 4 ; S2 closed tPZL; Tri-state to Output LOW 2.80 10.0 µs CL = 100pF, Fig. 4 & 6; S1 closed tPZH; Tri-state to Output HIGH 0.10 2.0 µs CL = 100pF, Fig. 4 & 6; S2 closed tPLZ; Output LOW to Tri-state 0.10 2.0 µs CL = 15pF, Fig. 4 & 6; S1 closed tPHZ; Output HIGH to Tri-state 0.10 2.0 µs CL = 15pF, Fig. 4 & 6; S2 closed tPZL; Tri-state to Output LOW 2.60 10.0 µs CL = 100pF, Fig. 4 & 6; S1 closed tPZH; Tri-state to Output HIGH 0.10 2.0 µs CL = 100pF, Fig. 4 & 6; S2 closed tPLZ; Output LOW to Tri-state 0.10 2.0 µs CL = 15pF, Fig. 4 & 6; S1 closed tPHZ; Output HIGH to Tri-state 0.15 2.0 µs CL = 15pF, Fig. 4 & 6; S2 closed RS-423 MODE RS-422, RS-485 MODES V.35 MODE Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com  SP504_102_121708 OTHER AC CHARACTERISTICS TA = +70°C to 0°C and VCC = +4.75V to +5.25V unless otherwise noted. PARAMETER MIN. TYP. MAX. UNITS CONDITIONS RECEIVER DELAY TIME BETWEEN ACTIVE MODE AND TRI-STATE MODE RS-232 Mode tPZL; Tri-state to Output LOW 0.12 2.0 µs CL = 100pF, Fig. 2 ; S1 closed tPZH; Tri-state to Output HIGH 0.10 2.0 µs CL = 100pF, Fig. 2 ; S2 closed tPLZ; Output LOW to Tri-state 0.10 2.0 µs CL = 100pF, Fig. 2 ; S1 closed tPHZ; Output HIGH to Tri-state 0.10 2.0 µs CL = 100pF, Fig. 2 ; S2 closed tPZL; Tri-state to Output LOW 0.10 2.0 µs CL = 100pF, Fig. 2 ; S1 closed tPZH; Tri-state to Output HIGH 0.10 2.0 µs CL = 100pF, Fig. 2 ; S2 closed tPLZ; Output LOW to Tri-state 0.10 2.0 µs CL = 100pF, Fig. 2 ; S1 closed tPHZ; Output HIGH to Tri-state 0.10 2.0 µs CL = 100pF, Fig. 2 ; S2 closed tPZL; Tri-state to Output LOW 0.10 2.0 µs CL = 100pF, Fig. 2 & 8; S1 closed tPZH; Tri-state to Output HIGH 0.10 2.0 µs CL = 100pF, Fig. 2 & 8; S2 closed tPLZ; Output LOW to Tri-state 0.10 2.0 µs CL = 15pF, Fig. 2 & 8; S1 closed tPHZ; Output HIGH to Tri-state 0.10 2.0 µs CL = 15pF, Fig. 2 & 8; S2 closed tPZL; Tri-state to Output LOW 0.10 2.0 µs CL = 100pF, Fig. 2 & 8; S1 closed tPZH; Tri-state to Output HIGH 0.10 2.0 µs CL = 100pF, Fig. 2 & 8; S2 closed tPLZ; Output LOW to Tri-state 0.10 2.0 µs CL = 15pF, Fig. 2 & 8; S1 closed tPHZ; Output HIGH to Tri-state 0.10 2.0 µs CL = 15pF, Fig. 2 & 8; S2 closed TRANSCEIVER TO TRANSCEIVER SKEW [(tPHL-tPLH)Trcvr1 - (tPHL - tPLH)TRCVRX] RS-423 MODE RS-422, RS-485 MODES V.35 MODE RS-232 Driver 20 50 ns VCC = +5.0V, TA @ 25ºC RS-232 Receiver 20 50 ns VCC = +5.0V, TA @ 25ºC RS-422 Driver 20 50 ns VCC = +5.0V, TA @ 25ºC RS-422 Receiver 20 50 ns VCC = +5.0V, TA @ 25ºC RS-423 Driver 20 50 ns VCC = +5.0V, TA @ 25ºC RS-423 Receiver 20 50 ns VCC = +5.0V, TA @ 25ºC V.35 Driver 20 50 ns VCC = +5.0V, TA @ 25ºC V.35 Receiver 20 50 ns VCC = +5.0V, TA @ 25ºC Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com  SP504_102_121708 A VOD 1KΩ VOC S2 B Figure 1. Driver DC Test Load Circuit DI A B CL1 RL CL2 A B Figure 2. Receiver Timing Test Load Circuit DI RO Output Under Test A A B B RO 15pF 15pF Figure 3a. Driver / Receiver Timing Test Circuit 500Ω VCC S1 CRL R 1KΩ Test Point Receiver Output R S1 Figure 3b.Timing Test Circuit (V.35 Mode only) VCC CL S2 Figure 4.Driver Timing Test Load #2 Circuit Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com  SP504_102_121708 DRIVER INPUT f = 1MHz; TR ≤ 10ns; TF ≤ 10nS +3V A DRIVER OUTPUT 1.5V 0V B 1.5V t PLH t PHL VO 1/2VO 1/2VO DIFFERENTIAL VO+ 0V OUTPUT VO– VA - VB t SKEW t SKEW tF tR Figure 5. Driver Propagation Delays TDECx A, B A, B f = 1MHz; t R < 10ns; t F < 10ns +3V 1.5V 0V 1.5V t ZL 5V 2.3V VOL VOH 2.3V 0V t LZ Output normally LOW 0.5V Output normally HIGH 0.5V t ZH t HZ Figure 6. Driver Enable and Disable Times A– B f = 1MHz; t R ≤ 10ns ; t F ≤ 10ns VOD2 + 0V VOD2 – VOH RECEIVER OUT VOL 0V INPUT 1.5V 1.5V OUTPUT t PHL t PLH Figure 7. Receiver Propagation Delays Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 10 SP504_102_121708 RDECx +3V RECEIVER OUT 0V 1.5V f = 1MHz; t ≤ 10ns; t ≤ 10ns R F t ZL 5V VIL 1.5V VIH RECEIVER OUT 0V 1.5V t ZH 1.5V DRIVER INPUT t LZ Output normally LOW 0.5V Output normally HIGH 0.5V t HZ DRIVER OUTPUT Figure 8. Receiver Enable and Disable Times Figure 9. Typical RS-232 Driver Output Waveform DRIVER INPUT DRIVER INPUT DRIVER OUTPUT DRIVER OUTPUT Figure 10. Typical RS-423 Driver Output Waveform Figure 11. Typical RS-422/RS-485 Driver Output Waveform V.35 Driver VOD over Temperature DRIVER INPUT 0.825 0.66 VOD+ 0.495 V.35 VOD 0.33 DRIVER OUTPUT 0.65 0 -0.65 -0.33 -0.495 VOD- -0.66 Vcc = 5.0V -0.825 0 0 20 30 40 50 60 70 Temperature (deg C) Figure 12. Typical V.35 Driver Output Waveform Figure 13. V.35 Driver Output VOD VS. Temperature Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 11 SP504_102_121708 Pin 63 —  TT(a) —  Analog Out —  Terminal Timing, inverted; sourced from TxC 61 SD(a) 62 VCC 63 TT(a) 64 GND 65 TT(b) 66 CS(a) 67 CS(b) 69 DM(b) 70 RD(a) 68 DM(a) 71 RD(b) 72 GND 73 VCC 74 VCC 75 GND 76 SCT(a) 77 SCT(b) 78 DSR Pin 61 — SD(a) — Analog Out — Send data, inverted; sourced from TxD. 79 SCT 80 CTS PINOUT… RxD 1 Pin 65 — TT(b) —  Analog Out —  Terminal Timing, non–inverted; sourced from TxC. 60 GND RDEC0 2 59 SD(b) RDEC1 3 58 TR(a) RDEC2 4 57 GND RDEC3 5 56 TR(b) TTEN 6 55 VCC SCTEN 7 Pin 70 — RD(a) — Receive Data, analog input; inverted; source for RxD. 54 RS(a) N/C 8 53 GND SP504 TDEC3 9 TDEC2 10 TDEC1 11 Pin 71 — RD(b) — Receive Data; analog input; non-inverted; source for RxD. 52 RS(b) 51 LL(a) 50 GND TDEC0 12 49 LL(b) Pin 76 — SCT(a) — Serial Clock Transmit; analog input, inverted; source for SCT. Pin 77 — SCT(b) — Serial Clock Transmit: analog input, non–inverted; source for SCT IC(b) 40 IC(a) 39 RT(b) 38 RT(a) 37 RR(b) 36 RR(a) 35 GND 34 VCC 33 C2- 31 C2+ 28 VSS 32 41 VCC C1- 30 42 ST(a) RxC 20 GND 29 43 GND DCD 19 V DD 27 V35_STAT 18 C1+ 26 44 ST(b) VCC 25 45 RL(b) RL 17 LL 24 46 GND RTS 16 RI 21 47 RL(a) TxC 15 ST 22 48 VCC TxD 14 STEN 23 DTR 13 Pin 79 — SCT — Serial Clock Transmit; TTL output; sources from SCT(a) and SCT(b) inputs. PIN ASSIGNMENTS… CLOCK AND DATA GROUP Pin 1 — RxD — Receive Data; TTL output, sourced from RD(a) and RD(b) inputs. CONTROL LINE GROUP Pin 13 — DTR — Data Terminal Ready; TTL input; source for TR(a) and TR(b) outputs. Pin 14 — TxD — TTL input ; transmit data source for SD(a) and SD(b) outputs. Pin 16 — RTS — Ready To Send; TTL input; source for RS(a) and RS(b) outputs. Pin 15 — TxC — Transmit Clock; TTL input for TT driver outputs. Pin 17 — RL — Remote Loopback; TTL input; source for RL(a) and RL(b) outputs. Pin 20 — RxC — Receive Clock; TTL output sourced from RT(a) and RT(b) inputs. Pin 18 — V35_STAT — V.35 Status; TTL output; outputs logic high when in V.35 mode. Pin 22 — ST — Send Timing; TTL input; source for ST(a) and ST(b) outputs. Pin 37 — RT(a) — Receive Timing; analog input, inverted; source for RxC. Pin 19 — DCD— Data Carrier Detect; TTL output; sourced from RR(a) and RR(b) inputs. Pin 38 — RT(b) — Receive Timing; analog input, non-inverted; source for RxC. Pin 21 — RI — Ring Indicate; TTL output; sourced from IC(a) and IC(b) inputs. Pin 42 — ST(a) — Send Timing; analog output, inverted; sourced from ST. Pin 24 — LL — Local Loopback; TTL input; source for LL(a) and LL(b) outputs. Pin 44 — ST(b) — Send Timing; analog output, non-inverted; sourced from ST. Pin 35 — RR(a)— Receiver Ready; analog input, inverted; source for DCD. Pin 59 — SD(b) — Analog Out — Send data, non-inverted; sourced from TxD. Pin 36 — RR(b)— Receiver Ready; analog input, non-inverted; source for DCD. Pin 39 — IC(a)— Incoming Call; analog input, inverted; source for RI. Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 12 SP504_102_121708 Pins 12–9 — TDEC0 – TDEC3 — Transmitter decode register; configures transmitter modes; TTL inputs. Pin 40 — IC(b)— Incoming Call; analog input,non-inverted; source for RI. Pin 45 — RL(b) — Remote Loopback; analog output, non-inverted; sourced from RL. Pin 23 — STEN — Enables ST driver; active low; TTL input. Pin 47 — RL(a) — Remote Loopback; analog output inverted; sourced from RL. POWER SUPPLIES Pins 25, 33, 41, 48, 55, 62, 73, 74 — VCC — +5V input. Pin 49— LL(b) — Local Loopback; analog output, non-inverted; sourced from LL. Pin 51 — LL(a) — Local Loopback; analog output, inverted; sourced from LL. Pins 29, 34, 43, 46, 50, 53, 57, 60, 64, 72, 75 — GND — Ground. Pin 52 — RS(b) — Ready To Send; analog output, non-inverted; sourced from RTS. Pin 27 — VDD +10V Charge Pump Capacitor — Connects from VDD to VCC. Suggested capacitor size is 22µF, 16V. Pin 54 — RS(a) — Ready To Send; analog output, inverted; sourced from RTS. Pin 32 — VSS –10V Charge Pump Capacitor — Connects from ground to VSS. Suggested capacitor size is 22µF, 16V. Pin 56 — TR(b) — Terminal Ready; analog output, non-inverted; sourced from DTR. Pin 58 — TR(a) — Terminal Ready; analog output, inverted; sourced from DTR. Pins 26 and 30 — C1+ and C1– — Charge Pump Capacitor — Connects from C1+ to C1–. Suggested capacitor size is 22µF, 16V. Pin 66 — CS(a)— Clear To Send; analog input, inverted; source for CTS. Pins 28 and 31 — C2+ and C2– — Charge Pump Capacitor — Connects from C2+ to C2–. Suggested capacitor size is 22µF, 16V. Pin 67 — CS(b)— Clear To Send; analog input, non-inverted; source for CTS. Pin 68 — DM(a)— Data Mode; analog input, inverted; source for DSR. NOTE: NC pins should be left floating; internal signals may be present. Pin 69 — DM(b)— Data Mode; analog input, non-inverted; source for DSR Pin 78 — DSR— Data Set Ready; TTL output; sourced from DM(a), DM(b) inputs. Pin 80 — CTS— Clear To Send; TTL output; sourced from CS(a) and CS(b) inputs. CONTROL REGISTERS Pins 2–5 — RDEC0 – RDEC3 — Receiver decode register; configures receiver modes; TTL inputs. Pin 6 — TTEN — Enables TT driver, active low; TTL input. Pin 7 — SCTEN — Enables SCT receiver; active high; TTL input. Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 13 SP504_102_121708 FEATURES… The SP504 is a highly integrated serial transceiver that allows software control of its interface modes. Similar to the SP503, the SP504 offers the same hardware interface modes for RS-232 (V.28), RS-422A (V.11), RS-449, RS-485, V.35, EIA-530 and includes V.36 and EIA-530A. The interface mode selection is done via an 8–bit switch; four (4) bits control the drivers and four (4) bits control the receivers. The SP504 is fabricated using low power BiCMOS process technology, and incorporates a Exar patented (5,306,954) charge pump allowing +5V only operation. Each device is packaged in an 80–pin JEDEC Quad FlatPack package. The SP504 charge pump is used for RS-232 where the output voltage swing is typically ±10V and also used for RS-423. However, RS-423 requires the voltage swing on the driver output be between ±4V to ±6V during an open circuit (no load). The charge pump would need to be regulated down from ±10V to ±5V. A typical ±10V charge pump would require external clamping such as 5V zener diodes on VDD and VSS to ground. The ±5V output has symmetrical levels as in the ±10V output. The ±5V is used in the following modes where RS-423 levels are used: RS449, EIA-530, EIA-530A and V.36. Phase 1 (±10V) — VSS charge storage — During this phase of the clock cycle, the positive side of capacitors C1 and C2 are initially charged to +5V. The Cl+ is then switched to ground and the charge on C1– is transferred to C2–. Since C2+ is connected to +5V, the voltage potential across capacitor C2 is now 10V. The SP504 is ideally suited for wide area network connectivity based on the interface modes offered and the driver and receiver configurations. The SP504 has seven (7) independent drivers and seven (7) independent receivers. In V.35 mode, the SP504 includes the necessary components and termination resistors internal within the device for compliant V.35 operation. Phase 1 (±5V) — VSS & VDD charge storage and transfer — With the C1 and C2 capacitors initially charged to +5V, Cl+ is then switched to ground and the charge on C1– is transferred to the VSS storage capacitor. Simultaneously the C2– is switched to ground and the 5V charge on C2+ is transferred to the VDD storage capacitor. Theory of Operation The SP504 is made up of five separate circuit blocks — the charge pump, drivers, receivers, decoder and switching array. Each of these circuit blocks is described in more detail below. VCC = +5V Charge–Pump The SP504's charge pump design is based on the SP503 where Exar's patented charge pump design (5,306,954) uses a four–phase voltage shifting technique to attain symmetrical ±10V power supplies. In addition, the SP504 charge pump incorporates a "programmable" feature that produces an output of ±10V or ±5V for VSS and VDD depending on the mode of operation. The charge pump still requires external capacitors to store the charge. Figure 18a shows the waveform found on the positive side of capacitor C2, and Figure 18b shows the negative side of capcitor C2. There is a free–running oscillator that controls the four phases of the voltage shifting. A description of each phase follows. +5V C1 + C2 – + C4 + – VDD Storage Capacitor + VSS Storage Capacitor – –5V – C3 –5V Figure 14a. Charge Pump Phase 1 for ±10V. VCC = +5V +5V C1 + – C2 + C4 + – VDD Storage Capacitor + VSS Storage Capacitor – –5V – C3 Figure 14b. Charge Pump Phase 1 for ±5V. Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 14 SP504_102_121708 VCC = +5V VCC = +5V C4 C1 + C2 – + + C4 – VDD Storage Capacitor C1 – –10V + – + – C2 + – Figure 15a. Charge Pump Phase 2 for ±10V. VSS Storage Capacitor VCC = +5V +5V – + Figure 15b. Charge Pump Phase 2 for ±5V. VCC = +5V C1 VDD Storage Capacitor C3 C3 + – – –5V VSS Storage Capacitor + C2 + C4 + – +10V VDD Storage Capacitor C1 – –5V – –5V + + – C2 + C4 + – VDD Storage Capacitor + VSS Storage Capacitor – – VSS Storage Capacitor C3 C3 Figure 16. Charge Pump Phase 3. Figure 17. Charge Pump Phase 4. Phase 2 (±10V) — VSS transfer — Phase two of the clock connects the negative terminal of C2 to the VSS storage capacitor and the positive terminal of C2 to ground, and transfers the generated –l0V or the generated –5V to C3. Simultaneously, the positive side of capacitor C 1 is switched to +5V and the negative side is connected to ground. transferred to the VSS storage capacitor. VSS receives a continuous charge from either C1 or C2. With the C1 capacitor charged to 5V, the cycle begins again. Phase 3 — VDD charge storage — The third phase of the clock is identical to the first phase — the charge transferred in C1 produces –5V in the negative terminal of C1, which is applied to the negative side of capacitor C2. Since C2+ is at +5V, the voltage potential across C2 is l0V. For the 5V output, C2+ is connected to ground so that the potential on C2 is only +5V. Phase 2 (±5V) — VSS & VDD charge storage — C1+ is reconnected to VCC to recharge the C1 capacitor. C2+ is switched to ground and C2– is connected to C3. The 5V charge from Phase 1 is now (a) +5V C 2+ GND (b) GND C 2– –5V +10V C 2+ GND GND C2 – –10V Figure 18a and 18b. Charge Pump Waveforms Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 15 SP504_102_121708 Since both VDD and VSS are separately generated from VCC in a no–load condition, VDD and VSS will be symmetrical. Older charge pump approaches that generate V– from V+ will show a decrease in the magnitude of V– compared to V+ due to the inherent inefficiencies in the design. The RS-232 drivers are used in RS232 mode for all signals, and also in V.35 mode where they are used as the control line signals such as DTR and RTS. The RS-423 drivers are also single–ended signals with a minimum voltage output of ±3.6V (with 450Ω loading) and can operate up to 120kbps. Open circuit VOL and VOH measurements are ±4.0V to ±6.0V. The RS423 drivers are used in RS-449, EIA-530, EIA-530A and V.36 modes as Category II signals from each of their corresponding specifications. The clock rate for the charge pump typically operates at 15kHz. The external capacitors must be a minimum of 22µF with a 16V breakdown rating. External Power Supplies For applications that do not require +5V only, external supplies can be applied at the V+ and V– pins. The value of the external supply voltages must be no greater than ±l0.5V. The tolerance should be ±5% from ±10V. The current drain for the supplies is used for RS-232 and RS-423 drivers. For the RS-232 driver, the current requirement will be 3.5mA per driver. The RS-423 driver worst case current drain will be 11mA per driver. Power sequencing is required for the SP504. The supplies must be sequenced accordingly: +10V, +5V and –10V. An external circuit would be needed for proper power supply sequencing. Consult factory for application circuitry. The third type of driver produces a differential signal that can maintain RS-485, ±1.5V differential output levels with a worst case load of 54Ω. The signal levels and drive capability of the RS-485 drivers allow the drivers to also support RS-422 (V.11) requirements of ±2V differential output levels with 100Ω loads. The RS-422 drivers are used in RS449, EIA-530, EIA-530A and V.36 modes as Category I signals which are used for clock and data. The fourth type of driver is the V.35 driver. V.35 levels require ±0.55V driver output signals with a load of 100Ω. The SP504 drivers simplify existing V.35 implementations that use external termination schemes. The drivers were specifically designed to comply with the requirements of V.35 as well as the driver output impedance values of V.35. The drivers achieve the 50Ω to 150Ω source impedance. However, an external 150Ω resistor to ground must be connected to the non-inverting outputs; SD(b), ST(b), and TT(b), in order to comply with the 135Ω to 165Ω short-circuit impedance for V.35. The V.35 driver itself is disabled and transparent when the decoder is in all other modes. All of the differential drivers; RS-485, RS-422, and V.35, can operate up to 10Mbps. Drivers The SP504 has seven (7) enhanced independent drivers. Control for the mode selection is done via a four–bit control word. The drivers are pre-arranged such that for each mode of operation, the relative position and functionality of the drivers are set up to accommodate the selected interface mode. As the mode of the drivers is changed, the electrical characteristics will change to support the requirements of clock, data, and control line signal levels. Table 1 shows the mode of each driver in the different interface modes that can be selected. There are four basic types of driver circuits — RS-232, RS-423, RS-485 and V.35. The driver inputs are both TTL or CMOS compatible. Since there are no pull-up or pull-down resistors on the driver inputs, they should be tied to a known logic state in order to define the driver output. The RS-232 drivers output single–ended signals with a minimum of ±5V (with 3kΩ and 2500pF loading), and can operate up to 120kbps. Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 16 SP504_102_121708 Receivers The SP504 has seven (7) independent receivers which can be programmed for the different interface modes. Control for the mode selection is done via a 4–bit control word that is independent from the driver control word. The coding for the drivers and receivers is identical. Therefore, if the modes for the drivers and receivers are supposed to be identical in the application, the control lines can be tied together. receivers. RS-422 receivers are used in RS-449, EIA-530, EIA-530A and V.36 as Category I signals for receiving clock, data, and some control line signals. The differential receivers can receive data up to 10Mbps. The RS-485 receivers are also used for the V.35 mode. Unlike the older implementations of differential or V.35 receivers, the SP504 contains an internal resistor termination network that ensures a V.35 input impedance of 100Ω (±10Ω) and a short-circuit impedance of 150Ω (±15Ω). The traditional V.35 implementations required external termination resistors to acheive the proper V.35 impedances. The internal network is connected via low on-resistance FET switches when the decoder is changed to V.35 mode. The termination network is transparent when all other modes are selected. The V.35 receivers can operate up to 10Mbps. Like the drivers, the receivers are pre-arranged for the specific requirements of the interface. As the operating mode of the receivers is changed, the electrical characteristics will change to support the requirements of clock, data, and control line receivers. Table 2 shows the mode of each receiver in the different interface modes that can be selected. There are three basic types of receiver circuits — RS-232, RS-423, and RS-485. All receivers include a fail-safe feature that outputs a logic HIGH when the receiver inputs are open. For single-ended RS-232 receivers, there are internal 5kΩ pull-down resistors on the inputs which produces a logic HIGH ("1") at the receiver outputs. The single-ended RS-423 receivers produce a logic LOW ("0") on the output when the inputs are open. This is due to a pull-up device connected to the input. The differential receivers have the same internal pull-up device on the non-inverting input which produces a logic HIGH ("1") at the receiver output. The three differential receivers when configured in V.35 mode (RxD, RxC & SCT) do not have fail-safe because the internal termination resistor network is connected. The RS-232 receiver is a single–ended input with a threshold of 0.8V to 2.4V. The RS-232 receiver has an operating voltage range of ±15V and can receive signals up to 120kbps. The input sensitivity complies with EIA-RS-232 and V.28 at +3V to -3V. The input impedance is 3kΩ to 7kΩ. RS232 receivers are used in RS-232 mode for all data, clock and control signals. They are also used in V.35 mode for control line signals such as CTS and DSR. The RS-423 receivers are also single–ended but have an input threshold as low as ±200mV. The input impedance is guaranteed to be greater than 4kΩ, with an operating voltage range of ±7V. The RS-423 receivers can operate up to 120kbps. RS-423 receivers are used in RS-449, EIA-530, EIA-530A and V.36 modes as Category II signals as indicated by their corresponding specifications. Decoder The SP504 has the ability to change the interface mode of the drivers or receivers via an 8–bit switch. The decoder for the drivers and receivers is not latched; it is merely a combinational logic switch. The third type of receiver is a differential which supports RS-485. The RS-485 receiver has an input impedance of 15kΩ and a differential threshold of ±200mV. Since the characteristics of an RS-422 (V.11) receiver are actually subsets of RS-485, the receivers for RS-422 requirements are covered by the RS-485 The control word can be externally latched either HIGH or LOW to write the appropriate code into the SP504. The codes shown in Tables 1 and 2 are the only specified, valid modes for the SP504. Undefined codes Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 17 SP504_102_121708 may represent other interface modes not specified (consult the factory for more information). The drivers are controlled with the data bits labeled TDEC3–TDEC0. All of the drivers can be put into tri-state mode by writing 0000 to the driver decode switch. The three drivers TxD, ST and TxC, have a 150Ω pull-down resistor to ground connected at the (b) output. This resistor is part of the V.35 driver circuitry and should be connected when in V.35 mode. Tri-state is possible for all drivers in RS-232 mode. The receivers are controlled with data bits RDEC3–RDEC0; the code 0000 written to the receivers will place the outputs into tri-state mode. The 0000 decoder word will override the enable control line for the one receiver (SCT). Using the V.35_STAT Pin The SP504 includes a V.35 status pin where the V35_STAT pin (pin 18) is a logic HIGH ("1") when the decoder is set to V.35 mode. The pin is a logic LOW ("0") when in all other modes including tri-state (decoder set at "0000"). Pin 18 allows the user to easily add FET switches or solid state relays to connect the external 150Ω resistor for V.35 operation. V35_STAT can be connected to the gate of the FET switches or the control of the relays so that the 150Ω resistors are connected to the non-inverting output of the three V.35 drivers. The output current of the V35_STAT pin is that of a typical TTL load of –3.2mA. The electrical specifications are similar to the SP504 receiver outputs. This feature would reduce additional logic required by older traditional methods. NET1/NET2 Testing and Compliancy Many system designers are required to certify their system for use in the European public network. Electrical testing is performed in adherence to the NET (Norme Européenne de Télécommunication) which specifies the ITU Series V specifications. The SP504 adheres to all the required physical layer testing for NET1 and NET2. Consult factory for details. Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 18 SP504_102_121708 SP504 Driver Mode Selection Pin Label Mode: RS232 V.35 RS422 RS485 RS449 EIA530 EIA-530A TDEC3 - TDEC0 0000 0010 1110 0100 0101 1100 1101 1111 0110 SD(a) tri-state V.28 V.35– V.11– RS485– V.11– V.11– V.11– V.11– SD(b) tri-state tri-state V.35+ V.11+ RS485+ V.11+ V.11+ V.11+ V.11+ TR(a) tri-state V.28 V.28 V.11– RS485– V.11– V.11– V.10 V.10 TR(b) tri-state tri-state tri-state V.11+ RS485+ V.11+ V.11+ tri-state tri-state RS(a) tri-state V.28 V.28 V.11– RS485– V.11– V.11– V.11– V.10 RS(b) tri-state tri-state tri-state V.11+ RS485+ V.11+ V.11+ V.11+ tri-state RL(a) tri-state V.28 V.28 V.11– RS485– V.10 V.10 V.11– V.10 RL(b) tri-state tri-state tri-state V.11+ RS485+ tri-state tri-state V.11+ tri-state LL(a) tri-state V.28 V.28 V.11– RS485– V.10 V.10 V.10 V.10 LL(b) tri-state tri-state tri-state V.11+ RS485+ tri-state tri-state tri-state tri-state ST(a) tri-state V.28 V.35– V.11– RS485– V.11– V.11– V.11– V.11– ST(b) tri-state tri-state V.35+ V.11+ RS485+ V.11+ V.11+ V.11+ V.11+ TT(a) tri-state V.28 V.35– V.11– RS485– V.11– V.11– V.11– V.11– TT(b) tri-state tri-state V.35+ V.11+ RS485+ V.11+ V.11+ V.11+ V.11+ V.36 Table 1. Driver Mode Selection SP504 Receiver Mode Selection Pin Label Mode: RS232 V.35 RS422 RS485 RS449 EIA530 EIA-530A V.36 RDEC3 - RDEC0 0000 0010 1110 0100 0101 1100 1101 1111 0110 RD(a) >12kΩ to GND V.28 V.35– V.11– RS485– V.11– V.11– V.11– V.11– RD(b) >12kΩ to GND >12kΩ to GND V.35+ V.11+ RS485+ V.11+ V.11+ V.11+ V.11+ RT(a) >12kΩ to GND V.35– V.11– RS485– V.11– V.11– V.11– V.11– RT(b) >12kΩ to GND >12kΩ to GND V.35+ V.11+ RS485+ V.11+ V.11+ V.11+ V.11+ CS(a) >12kΩ to GND CS(b) >12kΩ to GND >12kΩ to GND DM(a) >12kΩ to GND DM(b) >12kΩ to GND >12kΩ to GND RR(a) >12kΩ to GND RR(b) >12kΩ to GND >12kΩ to GND IC(a) >12kΩ to GND IC(b) >12kΩ to GND >12kΩ to GND V.28 V.28 V.28 V.28 V.28 SCT(a) >12kΩ to GND SCT(b) >12kΩ to GND >12kΩ to GND V.28 V.28 >12kΩ to GND V.11– RS485– V.11– V.11– V.11– V.11+ RS485+ V.11+ V.11+ V.11+ V.10 >12kΩ to GND V.10 V.11– RS485– V.11– V.11– V.10 V.11+ RS485+ V.11+ V.11+ >12kΩ to GND V.28 V.11– RS485– V.11– V.11– V.11– >12kΩ to GND V.11+ RS485+ V.11+ V.11+ V.11+ V.28 V.11– RS485– >12kΩ to GND V.11+ RS485+ V.35– V.11– RS485– V.11– V.11– V.11– V.11– V.35+ V.11+ RS485+ V.11+ V.11+ V.11+ V.11+ V.28 >12kΩ to GND V.10 >12kΩ to GND >12kΩ to GND V.10 >12kΩ to GND V.10 V.10 V.10 >12kΩ to GND >12kΩ to GND >12kΩ to GND Table 2. Receiver Mode Selection Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 19 SP504_102_121708 1N5819 22µF 22µF +5V 25 10µF VCC 22µF 31 27 26 VDD C1+ C1- C2+ 30 28 Charge Pump 14 TxD 61 SD(a) RxD 1 59 SD(b) RD(b) 71 RT (a) 37 13 DTR 16 RTS 54 RS(a) CTS 80 52 RS(b) CS(b) 67 17 RL DM(a) 68 47 RL(a) DSR 78 45 RL(b) DM (b) 69 24 LL RR(a) 35 51 LL(a) DCD 19 49 LL(b) A — Receiver Tri-State Circuitry & V.35 terminaiton resistor circuitry for RR(b) 36 RxD, RxC & SCT . 22 ST IC(a) 39 42 ST(a) RI 21 44 ST(b) IC(b) 40 23 STEN SCT(a) 76 Note 1 63 TT(a) 65 TT(b) SCTEN 7 SCT(b) 77 150Ω Note 1 X RDEC X 6 TTEN TDEC External Latch 150Ω 15 TxC SCT 79 0 1 0 0 0 1 0 0 Note 1 56 TR(b) RT (b) 38 CS(a) 66 5 4 3 2 9 10 11 12 150Ω 58 TR(a) RxC 20 RS-422 Mode Input Word 22µF 32 B A RD(a) 70 B — Driver Tri-State circuitry & V.35 termination circuitry for TxD, TxC & ST . C2VSS SP504 (SEE PAGE 12 FOR GROUND PINS) Note 1 For V.35 Termination, needs to be connected for proper V.35 operation. A low onresistance (≤1Ω) FET or switch can be used to connect and disconnect the resistor from the non-inverting output. Figure 19. SP504 Typical Operating Circuit Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 20 SP504_102_121708 MODE: RS-232 DRIVER RECEIVER TDEC3 TDEC 2 TDEC1 TDEC0 RDEC3 RDEC2 RDEC1 RDEC0 0 0 1 0 0 0 1 0 14 TxD RD(a) 70 61 SD(a) RxD 1 13 DTR RT(a) 37 58 TR(a) RxC 20 16 RTS CS(a) 66 54 RS(a) CTS 80 17 RL DM(a) 68 47 RL(a) DSR 78 24 LL RR(a) 35 DCD 19 51 LL(a) IC(a) 39 22 ST RI 21 42 ST(a) 23 STEN SCT(a) 76 15 TxC SCT 79 63 TT(a) SCTEN 7 6 TTEN RECEIVERS STEN DRIVERS 1 ST Disabled TTEN 1 TT Disabled SCTEN 1 SCT Enabled 0 Enabled 0 Enabled 0 Disabled Figure 20. Mode Diagram — RS-232 Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 21 SP504_102_121708 MODE: V.35 DRIVER RECEIVER TDEC 3 TDEC 2 TDEC 1 TDEC 0 RDEC 3 RDEC 2 RDEC 1 RDEC 0 1 1 1 0 1 1 1 0 14 TxD RD(a) 70 61 SD(a) RxD 1 59 SD(b) RD(b) 71 RT(a) 37 13 DTR 58 TR(a) RxC 20 16 RTS RT(b) 38 CS(a) 66 54 RS(a) CTS 80 17 RL DM(a) 68 47 RL(a) DSR 78 24 LL RR(a) 35 51 LL(a) DCD 19 22 ST IC(a) 39 42 ST(a) RI 21 44 ST(b) 23 STEN SCT(a) 76 15 TxC SCT 79 SCTEN 7 SCT(b) 77 STEN 1 0 63 TT(a) 65 TT(b) RECEIVERS ST Disabled Enabled TTEN 1 0 DRIVERS 6 TTEN TT SCTEN SCT Disabled 1 Enabled Enabled 0 Disabled Figure 21. Mode Diagram — V.35 Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 22 SP504_102_121708 MODE: RS-422 DRIVER RECEIVER TDEC 3 TDEC 2 TDEC 1 TDEC 0 RDEC 3 RDEC 2 RDEC 1 RDEC 0 0 1 0 0 0 1 0 0 14 TxD RD(a) 70 61 SD(a) RxD 1 59 SD(b) RD(b) 71 RT(a) 37 13 DTR 58 TR(a) RxC 20 55 TR(b) 16 RTS RT(b) 38 CS(a) 66 54 RS(a) 52 RS(b) CTS 80 17 RL CS(b) 67 DM(a) 68 47 RL(a) 45 RL(b) DSR 78 24 LL 51 LL(a) DM(b) 69 RR(a) 35 DCD 19 49 LL(b) 22 ST RR(b) 36 IC(a) 39 42 ST(a) 44 ST(b) RI 21 23 STEN IC(b) 40 SCT(a) 76 SCT 79 SCTEN 7 SCT(b) 77 STEN 1 0 15 TxC 63 TT(a) 65 TT(b) RECEIVERS DRIVERS 6 TTEN ST TT SCTEN TTEN Disabled 1 Disabled 1 Enabled 0 Enabled 0 SCT Enabled Disabled Figure 22. Mode Diagram — RS-422 Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 23 SP504_102_121708 MODE: RS-449 DRIVER RECEIVER TDEC 3 TDEC 2 TDEC 1 TDEC 0 RDEC 3 RDEC 2 RDEC 1 RDEC 0 1 1 0 0 1 1 0 0 14 TxD RD(a) 70 61 SD(a) RxD 1 59 SD(b) RD(b) 71 RT(a) 37 13 DTR 58 TR(a) RxC 20 55 TR(b) 16 RTS RT(b) 38 CS(a) 66 54 RS(a) 52 RS(b) CTS 80 17 RL CS(b) 67 DM(a) 68 47 RL(a) DSR 78 24 LL DM(b) 69 RR(a) 35 DCD 19 51 LL(a) 22 ST RR(b) 36 IC(a) 39 42 ST(a) 44 ST(b) RI 21 23 STEN SCT(a) 76 15 TxC 63 TT(a) SCT 79 SCTEN 7 SCT(b) 77 STEN 1 0 65 TT(b) RECEIVERS DRIVERS 6 TTEN ST TT SCTEN TTEN Disabled 1 Disabled 1 Enabled 0 Enabled 0 SCT Enabled Disabled Figure 23. Mode Diagram — RS-449 Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 24 SP504_102_121708 MODE: RS-485 DRIVER RECEIVER TDEC 3 TDEC 2 TDEC 1 TDEC 0 RDEC 3 RDEC 2 RDEC 1 RDEC 0 0 1 0 1 0 1 0 1 14 TxD RD(a) 70 61 SD(a) RxD 1 59 SD(b) RD(b) 71 RT(a) 37 13 DTR 58 TR(a) RxC 20 55 TR(b) 16 RTS RT(b) 38 CS(a) 66 54 RS(a) 52 RS(b) CTS 80 17 RL CS(b) 67 DM(a) 68 47 RL(a) 45 RL(b) DSR 78 24 LL 51 LL(a) DM(b) 69 RR(a) 35 DCD 19 49 LL(b) 22 ST RR(b) 36 IC(a) 39 42 ST(a) 44 ST(b) RI 21 23 STEN IC(b) 40 SCT(a) 76 SCT 79 SCTEN 7 SCT(b) 77 STEN 1 0 15 TxC 63 TT(a) 65 TT(b) RECEIVERS DRIVERS 6 TTEN ST TT SCTEN TTEN Disabled 1 Disabled 1 Enabled 0 Enabled 0 SCT Enabled Disabled Figure 24. Mode Diagram — RS-485 Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 25 SP504_102_121708 MODE: EIA-530 DRIVER RECEIVER TDEC 3 TDEC 2 TDEC 1 TDEC 0 RDEC 3 RDEC 2 RDEC 1 RDEC 0 1 1 0 1 1 1 0 1 14 TxD RD(a) 70 61 SD(a) RxD 1 59 SD(b) RD(b) 71 RT(a) 37 13 DTR 58 TR(a) RxC 20 55 TR(b) 16 RTS RT(b) 38 CS(a) 66 54 RS(a) 52 RS(b) CTS 80 17 RL CS(b) 67 DM(a) 68 47 RL(a) DSR 78 24 LL DM(b) 69 RR(a) 35 DCD 19 51 LL(a) 22 ST RR(b) 36 IC(a) 39 42 ST(a) 44 ST(b) RI 21 23 STEN SCT(a) 76 15 TxC 63 TT(a) SCT 79 SCTEN 7 SCT(b) 77 STEN 1 0 65 TT(b) RECEIVERS DRIVERS 6 TTEN ST TT SCTEN TTEN Disabled 1 Disabled 1 Enabled 0 Enabled 0 SCT Enabled Disabled Figure 25. Mode Diagram — EIA-530 Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 26 SP504_102_121708 MODE: EIA-530A DRIVER RECEIVER TDEC 3 TDEC 2 TDEC 1 TDEC 0 RDEC 3 RDEC 2 RDEC 1 RDEC 0 1 1 1 1 1 1 1 1 14 TxD RD(a) 70 61 SD(a) RxD 1 59 SD(b) RD(b) 71 RT(a) 37 13 DTR 58 TR(a) RxC 20 16 RTS RT(b) 38 CS(a) 66 54 RS(a) 52 RS(b) CTS 80 17 RL CS(b) 67 DM(a) 68 47 RL(a) 45 RL(b) DSR 78 24 LL RR(a) 35 51 LL(a) DCD 19 22 ST RR(b) 36 IC(a) 39 42 ST(a) 44 ST(b) RI 21 23 STEN SCT(a) 76 15 TxC 63 TT(a) SCT 79 SCTEN 7 SCT(b) 77 STEN 1 0 65 TT(b) RECEIVERS DRIVERS 6 TTEN ST TT SCTEN TTEN Disabled 1 Disabled 1 Enabled 0 Enabled 0 SCT Enabled Disabled Figure 26. Mode Diagram — EIA-530A Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 27 SP504_102_121708 MODE: V.36 DRIVER RECEIVER TDEC 3 TDEC 2 TDEC 1 TDEC 0 RDEC 3 RDEC 2 RDEC 1 RDEC 0 0 1 1 0 0 1 1 0 14 TxD RD(a) 70 61 SD(a) RxD 1 59 SD(b) RD(b) 71 RT(a) 37 13 DTR 58 TR(a) RxC 20 16 RTS RT(b) 38 CS(a) 66 54 RS(a) CTS 80 17 RL DM(a) 68 47 RL(a) DSR 78 24 LL RR(a) 35 51 LL(a) DCD 19 22 ST IC(a) 39 42 ST(a) RI 21 44 ST(b) 23 STEN SCT(a) 76 15 TxC SCT 79 SCTEN 7 SCT(b) 77 STEN 1 0 63 TT(a) 65 TT(b) RECEIVERS ST Disabled Enabled DRIVERS 6 TTEN TTEN TT SCTEN SCT 1 Disabled 1 Enabled 0 Enabled 0 Disabled Figure 27. Mode Diagram — V.36 Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 28 SP504_102_121708 Additional transceivers with the SP504 Serial ports usually can have two data signals (SD, RD), three clock signals (TT, ST, RT), and at least eight control signals (CS, RS, etc.). EIA-RS-449 contains twenty six signal types for a DB-37 connector. A DB37 serial port design may require thirteen drivers and fourteen receivers1. Although many applications do not use all these signals, some applications may need to support extra functions such as diagnostics. The SP504 supports enough transceivers for the primary channels of data, clock and control signals. Configuring LL, RL and TM would require two additional drivers and one receiver if designing for a DTE (one driver and two receivers for a DCE). the receiver is used for the TM signal. This configuration was selected because the two RS-232 drivers can be used for RS-423 by connecting a zener clamping diode to ground on the two driver outputs. The diodes will limit the voltage swing on the outputs so that the VOC = ±4V to ±6V adheres to the RS-423 specification. The differential receiver can be easily configured to RS-423 by grounding the non-inverting input. The receiver will adhere to the RS-423 specifications. A programmable transceiver such as the SP332 is a convenient solution in a design that requires extra single ended or differential drivers/receivers. As shown in Figure 28, the SP332 can be configured to four different variations. The SP332 in Figure 29 is configured for two single-ended drivers and one diffferential receiver. For a DTE design, the two drivers are used for LL and RL signals and 1 SG SC RC IS IC TR DM SD RD TT ST RT RS CS RR SQ NS SF SR SI SSD SRD SRS SCS SRR LL RL TM SS SB SIGNAL GROUND SEND COMMON RECEIVE COMMON TERMINAL IN SERVICE INCOMING CALL TERMINAL READY DATA MODE SEND DATA RECEIVE DATA TERMINAL TIMING SEND TIMING RECEIVE TIMING REQUEST TO SEND CLEAR TO SEND RECEIVER READY SIGNAL QUALITY NEW SIGNAL SELECT FREQUENCY SIGNAL RATE SELECTOR SIGNAL RATE INDICATOR SECONDARY SEND DATA SECONDARY RD SECONDARY RS SECONDARY CS SECONDARY RR LOCAL LOOPBACK REMOTE LOOPBACK TEST MODE SELECT STANDBY STANDBY INDICATOR CIRCUIT DIRECTION -------------- TO DCE FROM DCE TO DCE FROM DCE TO DCE FROM DCE TO DCE FROM DCE TO DCE FROM DCE FROM DCE TO DCE FROM DCE FROM DCE FROM DCE TO DCE TO DCE TO DCE FROM DCE TO DCE FROM DCE TO DCE FROM DCE FROM DCE TO DCE TO DCE FROM DCE TO DCE FROM DCE CIRCUIT TYPE COMMON CONTROL DATA TIMING CONTROL DATA CONTROL PRIMARY CHANNEL CIRCUIT NAME SECONDARY CHANNEL CIRCUIT MNEMONIC CONTROL CONTROL RS-449 Interchange Circuits Table SEL A 0 0 1 1 SEL B 0 1 0 1 LOOPBACK 1 1 1 1 SHUTDOWN 0 0 0 0 Figure 28. Mode selection for the SP332 Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 29 SP504_102_121708 1N5819 +5V 10µF 22µF 22µF 25 VCC Drivers 27 26 VDD 22µF 30 C1+ 28 31 C1V C2+ C2- SS TxD 14 4 22 12 30 7 25 17 35 58 56 54 RTS 16 52 63 TxC 15 65 42 ST 22 44 47 RL 17 16 45 51 LL 24 34 49 70 RxD 1 6 24 8 26 9 27 11 29 13 31 15 71 37 RxC 20 38 66 CTS 80 67 68 DSR 78 69 35 DCD 19 36 39 RI 21 TDEC 3 —TDEC 0 (pins 9-12) DB-37 Connector 61 59 DTR 13 Receivers 22µF 32 40 76 SCT 79 5 23 77 see pinout diagram for various ground pins SP504 "1100" for RS-449 mode RDEC 3 —RDEC 0 (pins 5-2) +5V 0.1µF 0.1µF Note: The SP332 will require clamping diodes on the driver outputs to limit the voltage to +/-6V and comply with the RS-423 driver output specification of Voc = +/-4.0V to +/-6.0V and VOUT ≥ +/-3.6V with a 450Ω load. 13 C2- VCC V+ 10 V- 14 SP332 0.1µF 10 µF 0.1µF 26 T1 6 LL 10 27 T2 7 RL 14 TM 18 28 0 1 5 9 C1+ 12 C111 C2+ T3 3 4 19 R1 15 20 R2 16 21 R3 24 2 SEL A SEL B LOOPBACK 18 17 23 8 1 Figure 29. Adding extra differential and single-ended transceivers using the SP332 Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 30 SP504_102_121708 PACKAGE: 80 Pin LQFP Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 31 SP504_102_121708 ORDERING INFORMATION Model Temperature Range Package Types SP504MCM-L....................................................................... 0°C to +70°C................................................................................................80–pin LQFP revision history DATE REVISION DESCRIPTION 01-27-04 A 7-7-08 1.0.0 Implemented tracking revision. SP504 is no longer available in MQFP package per PCN 07-1102-06a. SP514 is now only available in LQFP package compliant to RoHS. Changed to Exar datasheet format and revision to 1.0.0. 10/28/08 1.0.1 Added ESD rating of 500V HBM to electrical characteristics. 12/17/08 1.0.2 Add new V.35 Driver output VOD vs. Temperature graph and update figure numbers. Notice EXAR Corporation reserves the right to make changes to any products contained in this publication in order to improve design, performance or reliability. EXAR Corporation assumes no representation that the circuits are free of patent infringement. Charts and schedules contained herein are only for illustration purposes and may vary depending upon a user's specific application. While the information in this publication has been carefully checked; no responsibility, however, is assumed for inaccuracies. EXAR Corporation does not recommend the use of any of its products in life support applications where the failure or malfunction of the product can reasonably be expected to cause failure of the life support system or to significantly affect its safety or effectiveness. Products are not authorized for use in such applications unless EXAR Corporation receives, in writting, assurances to its satisfaction that: (a) the risk of injury or damage has been minimized ; (b) the user assumes all such risks; (c) potential liability of EXAR Corporation is adequately protected under the circumstances. Copyright 2008 EXAR Corporation Datasheet December 2008 Send your Interface technical inquiry with technical details to: uarttechsupport@exar.com Reproduction, in part or whole, without the prior written consent of EXAR Corporation is prohibited. Exar Corporation 48720 Kato Road, Fremont CA, 94538 • 510-668-7017 • www.exar.com 32 SP504_102_121708