Final Electrical Specifications LTC1546 Software-Selectable Multiprotocol Transceiver with Termination December 1999 U FEATURES ■ ■ ■ ■ ■ ■ ■ DESCRIPTIO The LTC®1546 is a 3-driver/3-receiver multiprotocol transceiver with on-chip cable termination. When combined with the LTC1544, this chip set forms a complete softwareselectable DTE or DCE interface port that supports the RS232, RS449, EIA530, EIA530-A, V.35, V.36 and X.21 protocols. All necessary cable termination is provided inside the LTC1546. In most applications, the LTC1546 replaces both an LTC1543 and an LTC1344A without any changes to the PC board. The LTC1546 runs from a single 5V supply using an internal charge pump that requires only five space-saving surface mounted capacitors. The LTC1546 is available in a 28-lead SSOP surface mount package. Software-Selectable Transceiver Supports: RS232, RS449, EIA530, EIA530-A, V.35, V.36, X.21 TUV Telecom Services Inc. Certified NET1, NET2 and TBR2 Compliant On-Chip Cable Termination Pin Compatible with LTC1543 Complete DTE or DCE Port with LTC1544 Operates from Single 5V Supply Small Footprint U APPLICATIO S ■ ■ Data Networking CSU and DSU Data Routers , LTC and LT are registered trademarks of Linear Technology Corporation. U ■ TYPICAL APPLICATIO Complete DTE or DCE Multiprotocol Serial Interface with DB-25 Connector LL CTS DSR DCD DTR RTS D2 D1 RXD TXC D3 R4 18 R2 R3 13 5 R1 10 8 TXD D3 D2 D1 T T T 12 15 11 24 14 LTC1546 LTC1544 D4 SCTE RXC 22 6 23 20 19 4 1 7 R3 R2 T T 16 3 9 R1 17 2 TXD A (103) TXD B SCTE A (113) SCTE B TXC A (114) TXC B RXC A (115) RXC B RXD A (104) RXD B SG (102) SHIELD (101) RTS A (105) RTS B DTR A (108) DCD A (107) DTR B DCD B DSR A (109) CTS A (106) DSR B CTS B LL A (141) DB-25 CONNECTOR 1546 TA01 Information furnished by Linear Technology Corporation is believed to be accurate and reliable. However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights. 1 LTC1546 W W W AXI U U ABSOLUTE RATI GS U U W PACKAGE/ORDER I FOR ATIO (Note 1) Supply Voltage ....................................................... 6.5V Input Voltage Transmitters ........................... – 0.3V to (VCC + 0.3V) Receivers ............................................... – 18V to 18V Logic Pins .............................. – 0.3V to (VCC + 0.3V) Output Voltage Transmitters ................. (VEE – 0.3V) to (VDD + 0.3V) Receivers ................................ – 0.3V to (VCC + 0.3V) VEE ........................................................ – 10V to 0.3V VDD ....................................................... – 0.3V to 10V Short-Circuit Duration Transmitter Output ..................................... Indefinite Receiver Output .......................................... Indefinite VEE .................................................................. 30 sec Operating Temperature Range LTC1546C ............................................... 0°C to 70°C LTC1546I ........................................... – 40°C to 85°C Storage Temperature Range ................ – 65°C to 150°C Lead Temperature (Soldering, 10 sec)................. 300°C ORDER PART NUMBER TOP VIEW C1– 1 C1+ 2 VDD 3 VCC 4 D1 5 D2 6 D3 7 R1 8 R2 9 28 C2 + 27 C2 – CHARGE PUMP 26 VEE 25 GND LTC1546CG LTC1546IG 24 D1 A D1 T D2 T 23 D1 B 22 D2 A 21 D2 B D3 20 D3/R1 A T R3 10 19 D3/R1 B R1 18 R2 A M0 11 M1 12 M2 13 R2 T R3 T 17 R2 B 16 R3 A 15 R3 B DCE/DTE 14 G PACKAGE 28-LEAD PLASTIC SSOP TJMAX = 150°C, θJA = 90°C/ W* *θJA SOLDERED TO A TYPICAL CIRCUIT BOARD IS TYPICALLY 60°C/W Consult factory for Military grade parts. ELECTRICAL CHARACTERISTICS The ● denotes specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VCC = 5V (Notes 2, 3) SYMBOL PARAMETER CONDITIONS VCC Supply Current (DCE Mode, All Digital Pins = GND or VCC) RS530, RS530-A, X.21 Modes, No Load RS530, RS530-A, X.21 Modes, Full Load V.35 Mode V.28 Mode, No Load V.28 Mode, Full Load No-Cable Mode MIN TYP MAX UNITS Supplies ICC PD Internal Power Dissipation (DCE Mode) RS530, RS530-A, X.21 Modes, Full Load V.35 Mode, Full Load V.28 Mode, Full Load V+ Positive Charge Pump Output Voltage V.11 or V.28 Mode, No Load V.35 Mode V.28 Mode, with Load V.28 Mode, with Load, IDD = 10mA V– Negative Charge Pump Output Voltage V.28 Mode, No Load V.28 Mode, Full Load V.35 Mode RS530, RS530-A, X.21 Modes, Full Load 2 14 100 126 20 35 60 ● ● ● ● ● ● ● 8.0 7.0 8.0 ● ● ● – 7.5 – 5.5 – 4.5 130 170 75 500 mA mA mA mA mA µA 410 625 150 mW mW mW 9.3 8.0 8.7 6.5 V V V V – 9.6 – 8.5 – 6.5 – 6.0 V V V V LTC1546 ELECTRICAL CHARACTERISTICS The ● denotes specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VCC = 5V (Notes 2, 3) SYMBOL PARAMETER fOSC Charge Pump Oscillator Frequency tr Charge Pump Rise Time CONDITIONS MIN No-Cable Mode/Power-Off to Normal Operation TYP MAX UNITS 500 kHz 2 ms Logic Inputs and Outputs VIH Logic Input High Voltage ● VIL Logic Input Low Voltage ● IIN Logic Input Current 2 V D1, D2, D3 M0, M1, M2, DCE = GND M0, M1, M2, DCE = VCC ● ● ● – 120 – 75 3 4.5 VOH Output High Voltage IO = – 3mA ● VOL Output Low Voltage IO = 3mA ● IOSR Output Short-Circuit Current 0V ≤ VO ≤ VCC ● IOZR Three-State Output Current M0 = M1 = M2 = VCC, 0V ≤ VO ≤ VCC VODO Open Circuit Differential Output Voltage RL = 1.95k (Figure 1) ● VODL Loaded Differential Output Voltage RL = 50Ω (Figure 1) RL = 50Ω (Figure 1) ● 0.3 – 50 0.8 V ±10 – 30 ±10 µA µA µA V 0.45 50 ±1 V mA µA V.11 Driver 0.5VODO ±2 ±5 V 0.67VODO V V ∆VOD Change in Magnitude of Differential Output Voltage RL = 50Ω (Figure 1) ● 0.2 V VOC Common Mode Output Voltage RL = 50Ω (Figure 1) ● 3 V ∆VOC Change in Magnitude of Common Mode Output Voltage RL = 50Ω (Figure 1) ● 0.2 V ISS Short-Circuit Current VOUT = GND IOZ Output Leakage Current VA and VB ≤ 0.25V, Power Off or No-Cable Mode or Driver Disabled ● t r, t f Rise or Fall Time (Figures 2, 13) ● t PLH Input to Output Rising (Figures 2, 13) t PHL Input to Output Falling (Figures 2, 13) ∆t Input to Output Difference, tPLH – tPHL (Figures 2, 13) t SKEW Output to Output Skew (Figures 2, 13) ±150 mA ±1 ±100 µA 2 15 25 ns ● 15 40 65 ns ● 15 40 65 ns ● 0 3 12 ns 3 ns V.11 Receiver VTH Input Threshold Voltage – 7V ≤ VCM ≤ 7V ● ∆VTH Input Hysteresis – 7V ≤ VCM ≤ 7V ● RIN Input Impedance –7V ≤ VCM ≤ 7V (Figure 3) ● t r, t f Rise or Fall Time CL = 50pF (Figures 4, 14) t PLH Input to Output Rising CL = 50pF (Figures 4, 14) ● 50 90 ns t PHL Input to Output Falling CL = 50pF (Figures 4, 14) ● 50 90 ns ∆t Input to Output Difference, tPLH – tPHL CL = 50pF (Figures 4, 14) ● 0 4 25 ns VOD Differential Output Voltage Open Circuit, RL = 1.95k (Figure 5) With Load, – 4V ≤ VCM ≤ 4V (Figure 6) ● ±0.44 ±0.55 ±1.2 ±0.66 V V VOA, VOB Single-Ended Output Voltage Open Circuit, RL = 1.95k (Figure 5) ● ±1.2 V VOC Transmitter Output Offset RL = 50Ω (Figure 5) ● ±0.6 V – 0.2 15 100 0.2 V 40 mV 103 Ω 15 ns V.35 Driver 3 LTC1546 ELECTRICAL CHARACTERISTICS The ● denotes specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VCC = 5V (Notes 2, 3) SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS IOH Transmitter Output High Current VA, VB = 0V ● – 13 – 11 – 9.0 mA IOL Transmitter Output Low Current VA, VB = 0V ● 9.0 11 13 mA IOZ Transmitter Output Leakage Current VA and VB ≤ 0.25V ● ±1 ±100 µA ROD Transmitter Differential Mode Impedance 50 100 150 Ω ROC Transmitter Common Mode Impedance – 2V ≤ VCM ≤ 2V (Figure 7) 135 150 165 Ω t r , tf Rise or Fall Time (Figures 8, 13) t PLH Input to Output (Figures 8, 13) ● 15 35 65 ns t PHL Input to Output (Figures 8, 13) ● 15 35 65 ns ∆t Input to Output Difference, tPLH – tPHL (Figures 8, 13) ● 0 16 ns t SKEW Output to Output Skew (Figures 8, 13) ● 5 ns 4 ns V.35 Receiver VTH Differential Receiver Input Threshold Voltage – 2V ≤ VCM ≤ 2V (Figure 9) ● ∆VTH Receiver Input Hysteresis – 2V ≤ VCM ≤ 2V (Figure 9) ● RID Receiver Differential Mode Impedance – 2V ≤ VCM ≤ 2V ● RIC Receiver Common Mode Impedance – 2V ≤ VCM ≤ 2V (Figure 10) t r, t f Rise or Fall Time CL = 50pF (Figures 4, 14) tPLH Input to Output CL = 50pF (Figures 4, 14) ● – 0.2 0.2 V 15 40 mV 90 103 110 Ω 135 150 165 Ω 15 ns 50 90 ns tPHL Input to Output CL = 50pF (Figures 4, 14) ● 50 90 ns ∆t Input to Output Difference, tPLH – tPHL CL = 50pF (Figures 4, 14) ● 0 4 25 ns VO Output Voltage Open Circuit RL = 3k (Figure 11) ● ● ±5 ±8.5 ±10 V V ISS Short-Circuit Current VOUT = GND ● ±150 mA ROZ Power-Off Resistance – 2V < VO < 2V, Power Off or No-Cable Mode ● 300 SR Slew Rate RL = 7k, CL = 0 (Figures 11, 15) ● 4 t PLH Input to Output RL = 3k, CL = 2500pF (Figures 11, 15) ● t PHL Input to Output RL = 3k, CL = 2500pF (Figures 11, 15) ● V.28 Driver Ω 30 V/µs 1.5 2.5 µs 1.5 2.5 µs 1.2 0.8 V V.28 Receiver VTHL Input Low Threshold Voltage (Figure 12) ● VTLH Input High Threshold Voltage (Figure 12) ● 2 1.2 ∆VTH Receiver Input Hysteresis (Figure 12) ● 0 0.05 0.3 RIN Receiver Input Impedance – 15V ≤ VA ≤ 15V ● 3 5 7 t r , tf tPLH Rise or Fall Time CL = 50pF (Figures 12, 16) Input to Output CL = 50pF (Figures 12, 16) ● 60 300 ns tPHL Input to Output CL = 50pF (Figures 12, 16) ● 160 300 ns Note 1: Absolute Maximum Ratings are those values beyond which the life of the device may be impaired. Note 2: All currents into device pins are positive; all currents out of device are negative. All voltages are referenced to device ground unless otherwise specified. 4 V V kΩ 15 ns Note 3: All typicals are given for VCC = 5V, C1 = C2 = CVCC = CVDD = 1µF, CVEE = 3.3µF and TA = 25°C. LTC1546 U U U PI FU CTIO S C1 –␣ (Pin 1): Capacitor C1 Negative Terminal. Connect a 1µF capacitor between C1+ and C1–. R3 B (Pin 15): Receiver 3 Noninverting Input. C1 + (Pin 2): Capacitor C1 Positive Terminal. Connect a 1µF capacitor between C1 + and C1 –. R2 B (Pin 17): Receiver 2 Noninverting Input. VDD (Pin 3): Generated Positive Supply Voltage for V.28. Connect a 1µF capacitor to ground. VCC (Pin 4): Positive Supply Voltage Input. 4.75V ≤ VCC ≤ 5.25V. Bypass with a 1µF capacitor to ground. D1 (Pin 5): TTL Level Driver 1 Input. D2 (Pin 6): TTL Level Driver 2 Input. D3 (Pin 7): TTL Level Driver 3 Input. R1 (Pin 8): CMOS Level Receiver 1 Output. R2 (Pin 9): CMOS Level Receiver 2 Output. R3 (Pin 10): CMOS Level Receiver 3 Output. M0 (Pin 11): TTL Level Mode Select Input 0 with Pull-Up to VCC. See Table 1. M1 (Pin 12): TTL Level Mode Select Input 1 with Pull-Up to VCC. See Table 1. M2 (Pin 13): TTL Level Mode Select Input 2 with Pull-Up to VCC. See Table 1. R3 A (Pin 16): Receiver 3 Inverting Input. R2 A (Pin 18): Receiver 2 Inverting Input. D3/R1 B (Pin 19): Receiver 1 Noninverting Input and Driver 3 Noninverting Output. D3/R1 A (Pin 20): Receiver 1 Inverting Input and Driver 3 Inverting Output. D2 B (Pin 21): Driver 2 Noninverting Output. D2 A (Pin 22): Driver 2 Inverting Output. D1 B (Pin 23): Driver 1 Noninverting Output. D1 A (Pin 24): Driver 1 Inverting Output. GND (Pin 25): Ground. VEE (Pin 26): Negative Supply Voltage. Connect a 3.3µF capacitor to GND. C2 – (Pin 27): Capacitor C2 Negative Terminal. Connect a 1µF capacitor between C2 + and C2 –. C2 + (Pin 28): Capacitor C2 Positive Terminal. Connect a 1µF capacitor between C2 + and C2 –. DCE/DTE (Pin 14): TTL Level Mode Select Input with PullUp to VCC. See Table 1. 5 LTC1546 W BLOCK DIAGRA CHARGE PUMP C1– 1 C1– C2+ 28 C2+ + C1 2 + C1 – C2 27 C2– VDD 3 VDD VEE 26 VEE VCC 4 VCC GND 25 GND 24 D1A 50Ω S1 D1 5 D1 S2 125Ω 50Ω 23 D1B 22 D2A 50Ω S1 D2 6 D2 S2 125Ω 50Ω 21 D2B D3 7 D3 20 D3/R1 A 10k 20k 6k S3 DCE/DTE 14 10k 51.5Ω S2 S1 125Ω 51.5Ω 20k 19 D3/R1 B R1 8 R1 20k 18 R2A 6k 10k R2 9 51.5Ω S3 R2 S2 125Ω 10k 51.5Ω 17 R2B 20k 20k 16 R3A 6k 10k R3 10 51.5Ω S3 R3 10k S2 125Ω 51.5Ω 15 R3B 20k 1546 BD 6 LTC1546 TEST CIRCUITS D RL B D VOD A RL B A VOC CL 100pF RL 100Ω CL 100pF 1546 F02 1546 F01 Figure 1. V.11 Driver DC Test Circuit IB Figure 2. V.11 Driver AC Test Circuit B R B IA VCM = ±7V A + – CL A 2(VB – VA) RIN = IB – IA 1546 F03 1546 F04 Figure 3. Input Impedance Test Circuit VOB Figure 4. V.11, V.35 Receiver AC Test Circuit VOB 50Ω 125Ω R RL 125Ω 50Ω 50Ω 50Ω 50Ω 125Ω 125Ω 50Ω VOD 50Ω VOC RL + – 50Ω VCM VCM = ±2V 1546 F05 1546 F07 1546 F06 VOA VOA Figure 5. V.35 Driver Open-Circuit Test Figure 6. V.35 Driver Test Circuit Figure 7. V.35 Driver Common Mode Impedance Test Circuit 51.5Ω 125Ω 50Ω 50Ω 50Ω 50Ω VTH + – 1546 F08 VCM + – 125Ω 125Ω VCM = ± 2V + – 51.5Ω 1546 F09 1546 F10 Figure 8. V.35 Driver AC Test Circuit D Figure 9. V.35 Receiver DC Test Circuit A A CL RL 1546 F11 Figure 11. V.28 Driver Test Circuit VA Figure 10. Receiver Common Mode Impedance Test Circuit R CL 1546 F12 Figure 12. V.28 Receiver Test Circuit 7 LTC1546 U W ODE SELECTIO Table 1 LTC1546 MODE NAME M2 M1 M0 DCE/DTE D1 D2 D3 R1 R2 R3 Not Used (Default V.11) 0 0 0 0 V.11 V.11 Z V.11 V.11 V.11 RS530A 0 0 1 0 V.11 V.11 Z V.11 V.11 V.11 RS530 0 1 0 0 V.11 V.11 Z V.11 V.11 V.11 X.21 0 1 1 0 V.11 V.11 Z V.11 V.11 V.11 V.35 1 0 0 0 V.35 V.35 Z V.35 V.35 V.35 RS449/V.36 1 0 1 0 V.11 V.11 Z V.11 V.11 V.11 V.28/RS232 1 1 0 0 V.28 V.28 Z V.28 V.28 V.28 No Cable 1 1 1 0 Z Z Z Z Z Z Not Used (Default V.11) 0 0 0 1 V.11 V.11 V.11 Z V.11 V.11 RS530A 0 0 1 1 V.11 V.11 V.11 Z V.11 V.11 RS530 0 1 0 1 V.11 V.11 V.11 Z V.11 V.11 X.21 0 1 1 1 V.11 V.11 V.11 Z V.11 V.11 V.35 1 0 0 1 V.35 V.35 V.35 Z V.35 V.35 RS449/V.36 1 0 1 1 V.11 V.11 V.11 Z V.11 V.11 V.28/RS232 1 1 0 1 V.28 V.28 V.28 Z V.28 V.28 No Cable 1 1 1 1 Z Z Z Z Z Z U W W SWITCHI G TI E WAVEFOR S 5V f = 1MHz : t r ≤ 10ns : t f ≤ 10ns 1.5V D 0V 1.5V t PHL t PLH VO B–A –VO 90% 90% 50% 10% tr 1/2 VO 50% 10% tf A VO B t SKEW t SKEW 1546 F13 Figure 13. V.11, V.35 Driver Propagation Delays VOD2 B–A –VOD2 VOH R VOL f = 1MHz : t r ≤ 10ns : t f ≤ 10ns 0V INPUT t PHL t PLH 1.5V OUTPUT 1.5V 1546 F14 Figure 14. V.11, V.35 Receiver Propagation Delays 8 0V LTC1546 U W W SWITCHI G TI E WAVEFOR S 3V 1.5V 1.5V D 0V t PHL VO t PLH 3V 0V A –VO SR = 6V tf –3V 3V SR = 6V tr 0V –3V tf 1546 F15 tr Figure 15. V.28 Driver Propagation Delays VIH 1.7V 1.3V A VIL t PHL t PLH VOH R VOL 2.4V 0.8V 1546 F16 Figure 16. V.28 Receiver Propagation Delays U W U U APPLICATIO S I FOR ATIO Overview The LTC1546 and LTC1544 form a complete softwareselectable DTE or DCE interface port that supports the RS232, RS449, EIA530, EIA530-A, V.35, V.36 and X.21 protocols. Cable termination is provided on-chip, eliminating the need for discrete termination designs. A complete DCE-to-DTE interface operating in EIA530 mode is shown in Figure 17. The LTC1546 half of each port is used to generate and appropriately terminate the clock and data signals. The LTC1544 is used to generate the control signals along with LL (Local Loopback). Mode Selection The interface protocol is selected using the mode select pins M0, M1 and M2 (see Table 1). For example, if the port is configured as a V.35 interface, the mode selection pins should be M2 = 1, M1 = 0, M0 = 0. For the control signals, the drivers and receivers will operate in V.28 (RS232) electrical mode. For the clock and data signals, the drivers and receivers will operate in V.35 electrical mode. The DCE/DTE pin will configure the port for DCE mode when high, and DTE when low. The interface protocol may be selected simply by plugging the appropriate interface cable into the connector. The mode pins are routed to the connector and are left unconnected (1) or wired to ground (0) in the cable as shown in Figure 18. The internal pull-up current sources will ensure a binary 1 when a pin is left unconnected. The mode selection may also be accomplished by using jumpers to connect the mode pins to ground or VCC. When the cable is removed, leaving all mode pins unconnected, the LTC1546/LTC1544 will enter no-cable mode. In this mode the LTC1546/LTC1544 supply current drops to less than 500µA and the LTC1546/LTC1544 driver outputs are forced into a high impedance state. At the same time, the R2 and R3 receivers of the LTC1546 are differentially terminated with 103Ω and the other receivers on the LTC1546 and LTC1544 are terminated with 30kΩ to ground. 9 LTC1546 U W U U APPLICATIO S I FOR ATIO SERIAL CONTROLLER DTE DCE LTC1546 LTC1546 SERIAL CONTROLLER TXD D1 TXD 103Ω R3 TXD SCTE D2 SCTE 103Ω R2 SCTE R1 D3 TXC R1 103Ω TXC D3 TXC RXC R2 103Ω RXC D2 RXC RXD R3 103Ω RXD D1 RXD LTC1544 LTC1544 RTS D1 RTS R3 RTS DTR D2 DTR R2 DTR D3 R1 DCD R1 DCD D3 DCD DSR R2 DSR D2 DSR CTS R3 CTS D1 CTS LL LL D4 R4 R4 LL D4 1546 F17 Figure 17. Complete Multiprotocol Interface in EIA530 Mode Cable Termination Traditional implementations used expensive relays to switch resistors or required the user to change termination modules every time a new interface standard was selected. Switching the terminations with FETs is difficult because the FETs must remain off when the signal voltage is beyond the supply voltage. Alternatively, custom cables 10 may contain termination in the cable head or route signals to various terminations on the board. The LTC1546/LTC1544 chipset solves the cable termination switching problem by automatically providing the appropriate termination and switching on-chip for the V.10 (RS423), V.11 (RS422), V.28 (RS232) and V.35 electrical protocols. LTC1546 U W U U APPLICATIO S I FOR ATIO (DATA) M0 LTC1546 M1 M2 DCE/DTE CONNECTOR 11 12 13 NC 14 NC CABLE DCE/DTE M2 LTC1544 M1 M0 14 13 12 11 (DATA) 1546 F18 Figure 18: Single Port DCE V.35 Mode Selection in the Cable BALANCED INTERCONNECTING CABLE V.10 (RS423) Interface All V.10 drivers and receivers necessary for the RS449, EIA530, EIA530-A, V.36 and X.21 protocols are implemented on the LTC1544. GENERATOR LOAD CABLE TERMINATION A typical V.10 unbalanced interface is shown in Figure 19. A V.10 single-ended generator with output A and ground C is connected to a differential receiver with input A' connected to A, and ground C' connected via the signal return to ground C. Usually, no cable termination is required for V.10 interfaces, but the receiver inputs must be compliant with the impedance curve shown in Figure 20. A A' C C' RECEIVER 1546 F19 Figure 19. Typical V.10 Interface IZ The V.10 receiver configuration in the LTC1544 is shown in Figure 21. In V.10 mode, switch S3 inside the LTC1544 is turned off. The noninverting input is disconnected inside the LTC1544 receiver and connected to ground. The cable termination is then the 30k input impedance to ground of the LTC1544 V.10 receiver. –10V 3.25mA –3V VZ 3V 10V V.11 (RS422) Interface A typical V.11 balanced interface is shown in Figure 22. A V.11 differential generator with outputs A and B and ground C is connected to a differential receiver with input A' connected to A, input B' connected to B, and ground C' connected via the signal return to ground C. The V.11 1546 F20 –3.25mA Figure 20. V.10 Receiver Input Impedance 11 LTC1546 U W U U APPLICATIO S I FOR ATIO A' A A' LTC1544 R8 6k R5 20k R1 51.5Ω R6 10k S3 LTC1546 R8 6k R6 10k RECEIVER S1 R3 124Ω S2 R4 20k B B' C' R7 10k B' GND Figure 21. V.10 Receiver Configuration GENERATOR A A' B B' C C' RECEIVER 100Ω MIN 1546 F22 interface has a differential termination at the receiver end that has a minimum value of 100Ω. The termination resistor is optional in the V.11 specification, but for the high speed clock and data lines, the termination is essential to prevent reflections from corrupting the data. The receiver inputs must also be compliant with the impedance curve shown in Figure 20. In V.11 mode, all switches are off except S1 of the LTC1546’s receivers which connects a 103Ω differential termination impedance to the cable as shown in Figure 231. The LTC1544 only handles control signals, so no termination other than its V.11 receivers’ 30k input impedance is necessary. 1546 F23 In V.28 mode, S3 is closed inside the LTC1546/LTC1544 which connects a 6k (R8) impedance to ground in parallel with 20k (R5) plus 10k (R6) for a combined impedance of 5k as shown in Figure 25. Proper termination is only provided when the B input of the receivers is floating, since S1 of the LTC1546’s R2 and R3 receivers remains on in V.28 mode1. The noninverting input is disconnected inside the LTC1546/LTC1544 receiver and connected to a TTL level reference voltage to give a 1.4V receiver trip point. A typical V.28 unbalanced interface is shown in Figure 24. A V.28 single-ended generator with output A and ground C is connected to a single-ended receiver with input A' there is no switch S1 in receivers R2 and R3. However, for simplicity, all termination networks on the LTC1546 can be treated identically if it is assumed that an S1 switch exists and is always closed on the R2 and R3 receivers. BALANCED INTERCONNECTING CABLE GENERATOR LOAD CABLE TERMINATION A A' C C' RECEIVER 1546 F24 Figure 24. Typical V.28 Interface A' LTC1546 R1 51.5Ω S1 S2 V.28 (RS232) Interface 12 GND connected to A and ground C' connected via the signal return to ground C. Figure 22. Typical V.11 Interface 1Actually, R7 10k R4 20k Figure 23. V.11 Receiver Configuration LOAD CABLE TERMINATION RECEIVER S3 R2 51.5Ω C' 1546 F21 BALANCED INTERCONNECTING CABLE R5 20k B' C' R8 6k R3 124Ω R5 20k R6 10k S3 R2 51.5Ω R4 20k RECEIVER R7 10k GND Figure 25. V.28 Receiver Configuration 1546 F25 LTC1546 U W U U APPLICATIO S I FOR ATIO V.35 Interface No-Cable Mode A typical V.35 balanced interface is shown in Figure 26. A V.35 differential generator with outputs A and B and ground C is connected to a differential receiver with input A' connected to A, input B' connected to B, and ground C' connected via the signal return to ground C. The V.35 interface requires a T or delta network termination at the receiver end and the generator end. The receiver differential impedance measured at the connector must be 100Ω␣ ±10Ω, and the impedance between shorted terminals (A' and B') and ground (C') must be 150Ω ±15Ω. The no-cable mode (M0 = M1 = M2 = 1) is intended for the case when the cable is disconnected from the connector. The charge pump, bias circuitry, drivers and receivers are turned off, the driver outputs are forced into a high impedance state, and the supply current drops to less than 200µA. Note that the LTC1546’s R2 and R3 receivers continue to be terminated by a 103Ω differential impedance. In V.35 mode, both switches S1 and S2 inside the LTC1546 are on, connecting a T network impedance as shown in Figure 27. The 30k input impedance of the receiver is placed in parallel with the T network termination, but does not affect the overall input impedance significantly. The LTC1546 uses an internal capacitive charge pump to generate VDD and VEE as shown in Figure 28. A voltage doubler generates about 8V on VDD and a voltage inverter generates about – 7.5V on VEE. Four 1µF surface mounted tantalum or ceramic capacitors are required for C1, C2, C3 and C4. The VEE capacitor C5 should be a minimum of 3.3µF. All capacitors are 16V and should be placed as close as possible to the LTC1546 to reduce EMI. The generator differential impedance must be 50Ω to 150Ω and the impedance between shorted terminals (A and B) and ground (C) must be 150Ω ±15Ω. BALANCED INTERCONNECTING CABLE GENERATOR 3 LOAD CABLE TERMINATION 125Ω 125Ω 50Ω B' C C' R8 6k S1 S2 R3 124Ω R5 20k R4 20k GND 28 C1+ C2 – 27 C2 1µF LTC1546 C1– VCC VEE GND 26 25 + C5 3.3µF Figure 28. Charge Pump Receiver Fail-Safe RECEIVER S3 R2 51.5Ω C2 + C4 1µF 1546 F26 R6 10k 4 VDD 1546 F28 LTC1546 R1 51.5Ω C1 1µF 1 5V 50Ω B A' C' RECEIVER 2 50Ω Figure 26. Typical V.35 Interface B' C3 1µF A' A 50Ω Charge Pump All LTC1546/LTC1544 receivers feature fail-safe operation in all modes. If the receiver inputs are left floating or are shorted together by a termination resistor, the receiver output will always be forced to a logic high. DTE vs DCE Operation R7 10k 1546 F27 Figure 27. V.35 Receiver Configuration The DCE/DTE pin acts as an enable for Driver 3/Receiver 1 in the LTC1546, and Driver 3/Receiver 1 and Driver 4/ Receiver 4 in the LTC1544. The INVERT pin in the LTC1544 allows the Driver 4/Receiver 4 enable to be high or low true polarity. 13 LTC1546 U W U U APPLICATIO S I FOR ATIO The LTC1546/LTC1544 can be configured for either DTE or DCE operation in one of two ways: a dedicated DTE or DCE port with a connector of appropriate gender or a port with one connector that can be configured for DTE or DCE operation by rerouting the signals to the LTC1546/LTC1544 using a dedicated DTE cable or dedicated DCE cable. A dedicated DTE port using a DB-25 male connector is shown in Figure 29. The interface mode is selected by logic outputs from the controller or from jumpers to either VCC or GND on the mode select pins. A dedicated DCE port using a DB-25 female connector is shown in Figure 30. A port with one DB-25 connector, that can be configured for either DTE or DCE operation is shown in Figure 31. The configuration requires separate cables for proper signal routing in DTE or DCE operation. For example, in DTE mode, the TXD signal is routed to Pins 2 and 14 via the LTC1546’s Driver 1. In DCE mode, Driver 1 now routes the RXD signal to Pins 2 and 14. Multiprotocol Interface with RL, LL, TM and a DB-25 Connector If the RL, LL and TM signals are implemented, there are not enough drivers and receivers available in the LTC1546/ LTC1544. In Figure 32, the required control signals are handled by the LTC1545. The LTC1545 has an additional single-ended driver/receiver pair that can handle two more optional control signals such as TM and RL. 14 Cable-Selectable Multiprotocol Interface A cable-selectable multiprotocol DTE/DCE interface is shown in Figure 33. The select lines M0, M1 and DCE/DTE are brought out to the connector. The mode is selected by the cable by wiring M0 (connector Pin 18) and M1 (connector Pin 21) and DCE/DTE (connector Pin 25) to ground (connector Pin 7) or letting them float. If M0, M1 or DCE/ DTE is floating, internal pull-up current sources will pull the signals to VCC. The select bit M2 is hard wired to VCC. When the cable is pulled out, the interface will go into the no-cable mode. Compliance Testing The LTC1546/LTC1544 chipset has been tested by TUV Telecom Services Inc. and passed the NET1, NET2 and TBR2 requirements. Copies of the test reports are available from LTC or TUV Telecom Services. The titles of the reports are: NET1 and NET2: Test Report No. NET2/091301/99. TBR2: Test Report No. CRT2/091301/99. The address of TUV Telecom Services Inc. is: TUV Telecom Services Inc. Type Approval Division 1775 Old Highway 8, Ste 107 St. Paul, MN 55112 USA TEL: +1 (612) 639-0775 FAX: +1 (612) 639-0873 LTC1546 U TYPICAL APPLICATIO S VCC 5V C1 1µF 28 1 27 26 CHARGE PUMP 2 4 25 C5 1µF LTC1546 5 TXD D1 6 SCTE T D2 C2 1µF T + C3 1µF 3 C4 3.3µF 24 2 23 14 22 24 21 11 20 15 19 12 18 17 17 9 16 3 15 16 TXD A (103) TXD B SCTE A (113) SCTE B 7 D3 8 TXC 11 12 13 14 C9 1µF RTS DTR T R2 10 RXD C10 1µF R1 9 RXC T T R3 M0 7 M1 M2 1 DCE/DTE VCC 1 VCC 2 VDD 3 VEE GND D1 4 D2 5 DSR CTS LL 6 R1 7 R2 8 R3 10 R4 9 M0 M1 M2 11 12 13 14 TXC B RXC A (115) RXC B RXD A (104) RXD B SG SHIELD DB-25 MALE CONNECTOR 28 C11 1µF 27 26 4 25 19 24 20 23 23 RTS A (105) RTS B DTR A (108) DTR B D3 LTC1544 DCD TXC A (114) 22 8 21 10 20 6 19 22 18 5 17 13 16 18 DCD A (109) DCD B DSR A (107) DSR B CTS A (106) CTS B LL A (141) D4 M0 INVERT 15 NC M1 M2 DCE/DTE 1546 F29 Figure 29. Controller-Selectable Multiprotocol DTE Port with DB-25 Connector 15 LTC1546 U TYPICAL APPLICATIO S VCC 5V C1 1µF 28 1 27 26 CHARGE PUMP 2 4 25 C5 1µF LTC1546 5 RXD D1 6 RXC T D2 C2 1µF T + C3 1µF 3 C4 3.3µF 24 3 23 16 22 17 21 9 20 15 19 12 18 24 17 11 16 2 15 14 RXD A (104) RXD B RXC A (115) RXC B 7 D3 8 TXC 11 12 13 NC C9 1µF 14 M0 7 M1 M2 1 DCE/DTE VCC 1 VCC 2 VDD VEE GND D1 4 DSR T R3 3 CTS T R2 10 TXD C10 1µF R1 9 SCTE T D2 5 LTC1544 R1 7 DTR R2 8 RTS R3 10 LL R4 9 11 M0 12 M1 13 M2 NC 14 TXC B SCTE A (113) SCTE B TXD A (103) TXD B SGND (102) SHIELD (101) DB-25 FEMALE CONNECTOR 28 C11 1µF 27 26 5 25 13 24 6 23 22 CTS A (106) CTS B DSR A (107) DSR B D3 6 DCD TXC A (114) 22 8 21 10 20 20 19 23 18 4 17 19 16 18 DCD A (109) DCD B DTR A (108) DTR B RTS A (105) RTS B LL A (141) D4 M0 INVERT 15 NC M1 M2 DCE/DTE 1546 F30 Figure 30. Controller-Selectable DCE Port with DB-25 Connector 16 LTC1546 U TYPICAL APPLICATIO S VCC 5V C1 1µF 28 1 27 26 CHARGE PUMP 2 4 25 C5 1µF LTC1546 5 DTE_TXD/DCE_RXD D1 6 DTE_SCTE/DCE_RXC C2 1µF T D2 T + C3 1µF 3 C4 3.3µF 24 2 23 14 22 24 21 11 20 15 19 12 18 17 17 9 16 3 15 16 DTE DCE TXD A RXD A TXD B RXD B SCTE A RXC A SCTE B RXC B TXC A TXC A TXC B TXC B RXC A SCTE A RXC B SCTE B RXD A TXD A RXD B TXD B 7 D3 8 DTE_TXC/DCE_TXC 11 12 13 14 DTE_RTS/DCE_CTS DTE_DTR/DCE_DSR C9 1µF T R2 10 DTE_RXD/DCE_TXD C10 1µF R1 9 DTE_RXC/DCE_SCTE T T R3 M0 7 M1 M2 1 DCE/DTE VCC 1 VCC 2 VDD 3 VEE GND D1 4 D2 5 DTE_DSR/DCE_DTR DTE_CTS/DCE_RTS DTE_LL/DCE_LL 6 R1 7 R2 8 R3 10 R4 9 M0 M1 M2 DCE/DTE 11 12 13 14 SHIELD DB-25 CONNECTOR 28 C11 1µF 27 26 4 25 19 24 20 23 23 RTS A CTS A RTS B CTS B DTR A DSR A DTR B DSR B DCD A DCD A D3 LTC1544 DTE_DCD/DCE_DCD SG 22 8 21 10 20 6 19 22 18 5 17 13 16 18 DCD B DCD B DSR A DTR A DSR B DTR B CTS A RTS A CTS B RTS B LL A LL A D4 M0 INVERT 15 NC M1 M2 DCE/DTE 1546 F31 Figure 31. Controller-Selectable Multiprotocol DTE/DCE Port with DB-25 Connector 17 LTC1546 U TYPICAL APPLICATIO S VCC 5V C1 1µF 28 1 27 26 CHARGE PUMP 2 4 25 C5 1µF LTC1546 5 DTE_TXD/DCE_RXD D1 T 6 DTE_SCTE/DCE_RXC D2 C2 1µF T + C3 1µF 3 C4 3.3µF 24 2 23 14 22 24 21 11 7 D3 8 DTE_TXC/DCE_TXC R2 10 DTE_RXD/DCE_TXD 11 R3 T T 20 15 19 12 18 17 17 9 16 3 15 16 M0 7 M1 13 M2 14 DCE/DTE 1 12 C10 1µF DTE_RTS/DCE_CTS DTE_DTR/DCE_DSR VCC 5V C9 1µF 1,19 VCC 2,20 VDD 3 VEE GND D1 4 D2 5 DTE_DSR/DCE_DTR DTE_CTS/DCE_RTS DTE_LL/DCE_RI DTE_RI/DCE_LL DTE_TM/DCE_RL DTE_RL/DCE_TM M0 M1 M2 DCE/DTE 6 R1 7 R2 8 R3 9 D4 10 R4 17 R5 18 11 12 13 14 TXD B RXD B SCTE A RXC A SCTE B RXC B TXC A TXC A TXC B TXC B RXC A SCTE A RXC B SCTE B RXD A TXD A RXD B TXD B SG SHIELD DB-25 CONNECTOR 36 C11 1µF 35 34 4 33 19 32 20 31 23 RTS A CTS A RTS B CTS B DTR A DSR A DTR B DSR B DCD A DCD A D3 LTC1545 DTE_DCD/DCE_DCD DCE RXD A T R1 9 DTE_RXC/DCE_SCTE DTE TXD A D5 M0 D4ENB M1 M2 R4EN 30 8 29 10 28 6 27 22 26 5 25 13 24 18 23 * 22 25 21 21 DCD B DCD B DSR A DTR A DSR B DTR B CTS A RTS A CTS B RTS B LL RI RI LL TM RL RL TM 15 *OPTIONAL 16 NC DCE/DTE 1546 F32 Figure 32. Controller-Selectable Multiprotocol DTE/DCE Port with RL, LL, TM and DB-25 Connector 18 LTC1546 U TYPICAL APPLICATIO S VCC 5V C1 1µF 28 1 27 26 CHARGE PUMP 2 4 25 C5 1µF LTC1546 5 DTE_TXD/DCE_RXD D1 6 DTE_SCTE/DCE_RXC C2 1µF + C3 1µF 3 T D2 T C4 3.3µF 24 2 23 14 22 24 21 11 20 15 19 12 18 17 17 9 16 3 15 16 7 D3 8 DTE_TXC/DCE_TXC R2 10 DTE_RXD/DCE_TXD 11 12 NC 13 14 DCE TXD A RXD A TXD B RXD B SCTE A RXC A SCTE B RXC B TXC A TXC A T R1 9 DTE_RXC/DCE_SCTE DTE R3 T T M0 7 M1 M2 1 DCE/DTE TXC B TXC B RXC A SCTE A RXC B SCTE B RXD A TXD A RXD B TXD B SG SHIELD DB-25 CONNECTOR C10 1µF C9 1µF VCC 1 VCC 2 VDD VEE GND 25 DCE/DTE 21 M1 18 M0 4 RTS A 19 RTS B 20 DTR A 23 DTR B 28 C11 1µF 27 26 3 DTE_RTS/DCE_CTS D1 24 4 DTE_DTR/DCE_DSR D2 5 LTC1544 R1 7 DTE_DSR/DCE_DTR R2 8 DTE_CTS/DCE_RTS R3 10 R4 9 11 12 NC 13 14 23 CTS A CTS B DSR A DSR B D3 6 DTE_DCD/DCE_DCD 25 22 8 21 10 20 6 19 22 18 5 17 13 M0 DCD B DSR A DTR A DSR B DTR B CTS A RTS A CTS B RTS B CABLE WIRING FOR DTE/DCE SELECTION M1 DCE/DTE INVERT DCD A DCD B CABLE WIRING FOR MODE SELECTION MODE PIN 18 PIN 21 V.35 PIN 7 PIN 7 RS449, V.36 NC PIN 7 RS232 PIN 7 NC 16 D4 M2 DCD A 15 NC MODE DTE DCE PIN 25 PIN 7 NC 1546 F33 Figure 33. Cable-Selectable Multiprotocol DTE/DCE Port with DB-25 Connector 19 LTC1546 U PACKAGE DESCRIPTIO Dimensions in inches (millimeters) unless otherwise noted. G Package 28-Lead Plastic SSOP (0.209) (LTC DWG # 05-08-1640) 10.07 – 10.33* (0.397 – 0.407) 28 27 26 25 24 23 22 21 20 19 18 17 16 15 7.65 – 7.90 (0.301 – 0.311) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 5.20 – 5.38** (0.205 – 0.212) 1.73 – 1.99 (0.068 – 0.078) 0° – 8° 0.13 – 0.22 (0.005 – 0.009) 0.55 – 0.95 (0.022 – 0.037) NOTE: DIMENSIONS ARE IN MILLIMETERS *DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.152mm (0.006") PER SIDE **DIMENSIONS DO NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED 0.254mm (0.010") PER SIDE 0.65 (0.0256) BSC 0.25 – 0.38 (0.010 – 0.015) 0.05 – 0.21 (0.002 – 0.008) G28 SSOP 1098 RELATED PARTS PART NUMBER DESCRIPTION COMMENTS LTC1321 Dual RS232/RS485 Transceiver Two RS232 Driver/Receiver Pairs or Two RS485 Driver/Receiver Pairs LTC1334 Single 5V RS232/RS485 Multiprotocol Transceiver Two RS232 Driver/Receiver or Four RS232 Driver/Receiver Pairs LTC1343 Software-Selectable Multiprotocol Transceiver 4-Driver/4-Receiver for Data and Clock Signals LTC1344A Software-Selectable Cable Terminator Perfect for Terminating the LTC1543 (Not Needed with LTC1546) LTC1345 Single Supply V.35 Transceiver 3-Driver/3-Receiver for Data and Clock Signals LTC1346A Dual Supply V.35 Transceiver 3-Driver/3-Receiver for Data and Clock Signals LTC1543 Software-Selectable Multiprotocol Transceiver Terminated with LTC1344A for Data and Clock Signals, Companion to LTC1544 or LTC1545 for Control Signals LTC1544 Software-Selectable Multiprotocol Transceiver Companion to LTC1546 or LTC1543 for Control Signals Including LL LTC1545 Software-Selectable Multiprotocol Transceiver 5-Driver/5-Receiver Companion to LTC1546 or LTC1543 for Control Signals Including LL, TM and RL 20 Linear Technology Corporation 1546i LT/TP 1299 4K • PRINTED IN USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408)432-1900 ● FAX: (408) 434-0507 ● www.linear-tech.com LINEAR TECHNOLOGY CORPORATION 1999