LTC2872CUHF#PBF

Features Four RS232 and Two RS485 Transceivers 3V to 5.5V Supply Voltage 20Mbps RS485 and 500kbps RS232 Automatic Selection of Integrated RS485 (120Ω) and RS232 (5kΩ) Termination Resistors Half-/Full-Duplex RS485 Switching Logic Loopback Mode High ESD: ±16kV on Line I/O 1.7V to 5.5V Logic Interface Supports Up to 256 RS485 Nodes RS485 Receiver Full Failsafe Eliminates UART Lockup Available in 38-Pin 5mm × 7mm QFN Package n n n n n n n n n n n LTC2872 RS232/RS485 Dual Multiprotocol Transceiver with Integrated Termination Description The LTC®2872 is a robust pin-configurable transceiver that supports RS232, RS485, and RS422 standards while operating on a single 3V to 5.5V supply. The LTC2872 can be configured as four RS232 single-ended transceivers or two RS485 differential transceivers, or combinations of both, on shared I/O lines. Pin-controlled integrated termination resistors allow for easy interface reconfiguration, eliminating external resistors and control relays. Half-duplex switches allow four-wire and two-wire RS485 configurations. Loopback mode steers the driver inputs to the receiver outputs for diagnostic self-test. The RS485 receivers support up to 256 nodes per bus, and feature full failsafe operation for floating, shorted or terminated inputs. Applications n n n n n n Flexible RS232/RS485/RS422 Interface Software Selectable Multiprotocol Interface Ports Point-of-Sale Terminals Cable Repeaters Protocol Translators PROFIBUS-DP Networks An integrated DC/DC boost converter uses a small inductor and one capacitor, eliminating the need for multiple supplies for driving RS232 levels. L, LT, LTC, LTM, Linear Technology, the Linear logo and µModule are registered trademarks of Linear Technology Corporation. All other trademarks are the property of their respective owners. Typical Applications RS485 Mode with Duplex Control 1.7V TO VCC 470nF RS485 FULL HALF DUPLEX 1.7V TO VCC 3V TO 5.5V 22µH 2.2µF 2.2µF VL CAP H/F RS232 Mode SW 3V TO 5.5V 22µH 1.7V TO VCC 2.2µF 2.2µF VCC VL CAP LTC2872 SW RS485 OFF ON RA1 DY2 A1 VDD Z1 RA1 A1 DY1 SW VCC LTC2872 Y1 120Ω Z1 A1 RA1 120Ω B1 B1 RB1 B1 Y2 DY2 Y2 DY2 Y2 DZ2 Z2 DZ2 Z2 RA2 A2 RA2 A2 RB2 B2 RB2 B2 VDD VEE VDD VEE Z2 RA2 TE485-1 TERMINATION DY1 3V TO 5.5V 22µH 2.2µF VL CAP Y1 DZ1 470nF 2.2µF VCC LTC2872 DY1 Y1 Z1 2.2µF 470nF Mixed Mode with RS485 Termination A2 B2 VEE 2.2µF 2.2µF 2.2µF 2.2µF 2872 TA01 2.2µF 2872f 1 LTC2872 Absolute Maximum Ratings Pin Configuration (Note 1) RB2 RA2 GND VL LB RA1 RB1 TOP VIEW 38 37 36 35 34 33 32 VCC 1 31 VCC A1 2 30 A2 B1 3 29 B2 Y1 4 28 Y2 GND 5 27 GND Z1 6 26 Z2 39 VEE DY1 7 25 DY2 DZ1 8 24 DZ2 RXEN1 9 23 RXEN2 DXEN1 10 22 DXEN2 21 VCC TE485_1 11 20 VDD TE485_2 12 SW GND CAP FEN H/F 485/232_2 13 14 15 16 17 18 19 485/232_1 Input Supplies VCC, VL...................................................... –0.3V to 7V Generated Supplies VDD................................................. VCC – 0.3V to 7.5V VEE.......................................................... 0.3V to –7.5V VDD – VEE...............................................................15V SW............................................ –0.3V to (VDD + 0.3V) CAP.............................................. 0.3V to (VEE – 0.3V) A1, A2, B1, B2, Y1, Y2, Z1, Z2.......................–15V to 15V DY1, DY2, DZ1, DZ2, RXEN1, RXEN2, DXEN1, DXEN2, LB, H/F, TE485_1, TE485_2, 485/232_1, 485/232_2................................. –0.3V to 7V FEN, RA1, RA2, RB1, RB2................–0.3V to (VL + 0.3V) Differential Enabled Terminator Voltage (A1-B1 or A2-B2 or Y1-Z1 or Y2-Z2)......................±6V Operating Temperature LTC2872C................................................. 0°C to 70°C LTC2872I..............................................–40°C to 85°C Storage Temperature Range................... –65°C to 125°C UHF PACKAGE 38-LEAD (5mm × 7mm) PLASTIC QFN TJMAX = 125°C, θJA = 34.7°C/W EXPOSED PAD (PIN #39) IS VEE, MUST BE SOLDERED TO PCB Order Information LEAD FREE FINISH TAPE AND REEL PART MARKING* PACKAGE DESCRIPTION TEMPERATURE RANGE LTC2872CUHF#PBF LTC2872CUHF#TRPBF 2872 38-Lead (5mm × 7mm) Plastic QFN 0°C to 70°C LTC2872IUHF#PBF LTC2872IUHF#TRPBF 2872 38-Lead (5mm × 7mm) Plastic QFN –40°C to 85°C Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container. Consult LTC Marketing for information on non-standard lead based finish parts. For more information on lead free part marking, go to: http://www.linear.com/leadfree/ For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/ 2872f 2 LTC2872 Electrical Characteristics The l denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VCC = VL = 3.3V, TE485_1 = TE485_2 = 0V, LB = 0V unless otherwise noted. SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS Power Supply VCC Supply Voltage Operating Range l 3 VL Logic Supply Voltage Operating Range VCC Supply Current in Shutdown Mode VL ≤ VCC l 1.7 VCC V RXEN1 = RXEN2 = VL, DXEN1 = DXEN2 = FEN = H/F = 0V l 8 60 µA VCC Supply Current in RS485 Transceiver Mode (Outputs Unloaded) (Note 3) 485/232_1 = 485/232_2 = DXEN1 = DXEN2 = VL, RXEN1 = RXEN2 = 0V l 4.5 7 mA VCC Supply Current in RS232 Transceiver Mode (Outputs Unloaded) (Note 3) DXEN1 = DXEN2 = VL; 485/232_1 = 485/232_2 = RXEN1 = RXEN2 = 0V l 5.5 8 mA l 0 5 µA 6 VCC VCC VCC V V V V 0.2 0.2 V V VL Supply Current in RS485 or RS232 Transceive DXEN1 = DXEN2 = VL, RXEN1 = RXEN2 = 0V Mode (Outputs Unloaded) 5.5 V RS485 Drivers |VOD| Differential Output Voltage RL = ∞, VCC = 3V (Figure 1) RL = 27Ω, VCC = 4.5V (Figure 1) RL = 27Ω, VCC = 3V (Figure 1) RL = 50Ω, VCC = 3.13V (Figure 1) l l l l ∆|VOD| Difference in Magnitude of Differential Output Voltage for Complementary Output States RL = 27Ω, VCC = 3V (Figure 1) RL = 50Ω, VCC = 3.13V (Figure 1) l l VOC Common Mode Output Voltage RL = 27Ω or 50Ω (Figure 1) l 3 V ∆|VOC| Difference in Magnitude of Common Mode RL = 27Ω or 50Ω (Figure 1) Output Voltage for Complementary Output States l 0.2 V IOZD485 Three-State (High Impedance) Output Current VOUT = 12V or –7V, VCC = 0V or 3.3V (Figure 2) l –100 125 µA IOSD485 Maximum Short-Circuit Current –7V ≤ VOUT ≤ 12V (Figure 2) l –250 250 mA l –100 125 µA 2.1 1.5 2 RS485 Receiver IIN485 Input Current VIN = 12V or –7V, VCC = 0V or 3.3V (Figure 3) (Note 5) RIN485 Input Resistance VIN = 12V or –7V, VCC = 0V or 3.3V (Figure 3) (Note 5) Differential Input Signal Threshold Voltage (A–B) –7V ≤ (A or B) ≤ 12 (Note 5) Differential Input Signal Hysteresis B = 0V (Notes 3, 5) Differential Input DC Failsafe Threshold Voltage (A–B) –7V ≤ (A or B) ≤ 12 (Note 5) Differential Input DC Failsafe Hysteresis B = 0V (Note 5) Output Low Voltage Output Low, I(RA) = 3mA (Sinking), 3V ≤ VL ≤ 5.5V l 0.4 V Output Low, I(RA) = 1mA (Sinking), 1.7V ≤ VL < 3V l 0.4 V Output High, I(RA) = –3mA (Sourcing), 3V ≤ VL ≤ 5.5V l VL – 0.4 V Output High, I(RA) = –1mA (Sourcing), 1.7V ≤ VL < 3V l VL – 0.4 V Three-State (High Impedance) Output Current 0V ≤ RA ≤ VL, VL = 5.5V l Short-Circuit Output Current 0V ≤ RA ≤ VL, VL = 5.5V l Terminating Resistor TE485 = VL, A–B = 2V, B = –7V, 0V, 10V (Figure 8) (Note 5) l VOL VOH RTERM Output High Voltage 125 kΩ ±200 l 190 l –200 –65 mV 0 30 0 108 120 mV mV mV ±5 μA ±135 mA 156 Ω 2872f 3 LTC2872 Electrical Characteristics The l denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VCC = VL = 3.3V, TE485_1 = TE485_2 = 0V, LB = 0V unless otherwise noted. SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS VEE V RS232 Driver VOLD Output Low Voltage RL = 3kΩ, VEE ≤ –6V l –5 –5.7 VOHD Output High Voltage RL = 3kΩ, VDD ≥ 6.5V l 5 6.2 Three-State (High Impedance) Output Current Y or Z = ±15V l Output Short-Circuit Current Y or Z = 0V l VDD V ±156 µA ±35 ±90 mA 2.5 V RS232 Receiver Input Threshold Voltage Input Hysteresis l 0.6 1.5 l 0.1 0.4 1.0 V 0.4 V Output Low Voltage I(RA, RB) = 1mA (Sinking), 1.7V ≤ VL ≤ 5.5V l Output High Voltage I(RA, RB) = –1mA (Sourcing), 1.7V ≤ VL ≤ 5.5V l VL – 0.4 Input Resistance –15V ≤ (A, B) ≤ 15V, Receiver Enabled l 3 5 7 kΩ Three-State (High Impedance) Output Current 0V ≤ (RA, RB) ≤ VL l 0 ±5 μA Output Short-Circuit Current VL = 5.5V, 0V ≤ (RA, RB) ≤ VL l ±25 ±50 mA V Logic Inputs Threshold Voltage l Input Current l 0.4 0 0.75• VL V ±5 µA Power Supply Generator VDD Regulated VDD Output Voltage VEE Regulated VEE Output Voltage RS232 Drivers Enabled, Outputs Loaded with RL = 3kΩ to GND, DY1 = DY2 = VL, DZ1 = DZ2 = 0V (Note 3) 7 V –6.3 V ESD Interface Pins (A, B, Y, Z) Human Body Model to GND or VCC, Powered or Unpowered (Note 7) ±16 kV All Other Pins Human Body Model (Note 7) ±4 kV 2872f 4 LTC2872 Switching Characteristics The l denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VCC = VL = 3.3V, TE485_1 = TE485_2 = 0V, LB = 0V unless otherwise noted. VL ≤ VCC. SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS RS485 AC Characteristics 20 Mbps Maximum Data Rate (Note 3) l Driver Propagation Delay RDIFF = 54Ω, CL = 100pF (Figure 4) l 20 70 ns Driver Propagation Delay Difference |tPLHD485 – tPHLD485| RDIFF = 54Ω, CL = 100pF (Figure 4) l 1 6 ns tSKEWD485 Driver Skew (Y to Z) RDIFF = 54Ω, CL = 100pF (Figure 4) l 1.5 ±8 ns tRD485, tFD485 Driver Rise or Fall Time RDIFF = 54Ω, CL = 100pF (Figure 4) l 7.6 15 ns tZLD485, tZHD485, tLZD485, tHZD485 Driver Output Enable or Disable Time FEN = VL, RL = 500Ω, CL = 50pF (Figure 5) l 120 ns tZHSD485, tZLSD485 Driver Enable from Shutdown FEN = 0V, RL = 500Ω, CL = 50pF (Figure 5) l 0.2 2 ms tPLHR485, tPHLR485 Receiver Input to Output CL = 15pF, VCM = 1.5V, |A–B| = 1.5V, (Figure 6) (Note 5) l 55 85 ns tSKEWR485 Differential Receiver Skew |tPLHR485 – tPHLR485| CL = 15pF (Figure 6) l 1 9 ns tRR485, tFR485 Receiver Output Rise or Fall Time CL = 15pF (Figure 6) l 3 15 ns tZLR485, tZHR485 tLZR485, tHZR485 Receiver Output Enable or Disable Time FEN = VL, RL = 1k, CL = 15pF (Figure 7) l 30 85 ns tRTEN485, tRTZ485 Termination Enable or Disable Time FEN = VL, VB = 0V, VAB = 2V (Figure 8) (Note 5) l 100 µs Maximum Data Rate RL = 3kΩ, CL = 2500pF, RL = 3kΩ, CL = 500pF (Note 3) l l 100 500 Driver Slew Rate (Figure 9) RL = 3kΩ, CL = 2500pF RL = 3kΩ, CL = 50pF l l 4 tPHLD232, tPLHD232 Driver Propagation Delay RL = 3kΩ, CL = 50pF (Figure 9) l 1 tSKEWD232 Driver Skew RL = 3kΩ, CL = 50pF (Figure 9) tZLD232, tZHD232 tLZD232, tHZD232 Driver Output Enable or Disable Time FEN = VL, RL = 3kΩ, CL = 50pF (Figure 10) l tPHLR232, tPLHR232 Receiver Propagation Delay CL = 150pF (Figure 11) l tSKEWR232 Receiver Skew CL = 150pF (Figure 11) tRR232, tFR232 Receiver Rise or Fall Time tZLR232, tZHR232, tLZR232, tHZR232 Receiver Output Enable or Disable Time tPLHD485 tPHLD485 RS232 AC Characteristics kbps kbps 30 V/µs V/µs 2 µs 0.4 2 µs 60 200 ns 50 ns 25 ns CL = 150pF (Figure 11) l 60 200 ns FEN = VL, RL = 1kΩ, CL = 150pF (Figure 12) l 0.7 2 µs FEN = l 0.2 2 ms Power Supply Generator VDD /VEE Supply Rise Time , (Notes 3 and 4) Note 1: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. Exposure to any Absolute Maximum Rating condition for extended periods may affect device reliability and lifetime. Note 2. All currents into device pins are positive; all currents out of device pins are negative. All voltages are referenced to device ground unless otherwise specified. Note 3. Guaranteed by other measured parameters and not tested directly. Note 4. Time from FEN until VDD ≥ 5V and VEE ≤ –5V. External components as shown in typical application. Note 5. Condition applies to A, B for H/F = 0V, and Y, Z for H/F = VL. Note 6. This IC includes overtemperature protection that is intended to protect the device during momentary overload conditions. Overtemperature protection activates at a junction temperature exceeding 150°C. Continuous operation above the specified maximum operating junction temperature may result in device degradation or failure. Note 7. Guaranteed by design and not subject to production test. 2872f 5 LTC2872 Typical Performance Characteristics VCC Supply Current vs Supply Voltage in Shutdown Mode VCC Supply Current vs Supply Voltage in Fast Enable Mode 4.6 30 H/F HIGH 20 15 H/F LOW 10 5 4.2 SUPPLY CURRENT (mA) SUPPLY CURRENT (mA) INPUT CURRENET (µA) 200 4.4 25 0 85°C 4.0 25°C 3.8 3.6 –40°C 3.4 3.5 3 4.5 4 INPUT VOLTAGE (V) 5 3.0 5.5 3.5 4 4.5 SUPPLY VOLTAGE (V) 5 0.5nF 30 0.05nF 25 20 2.5nF 0.5nF 0.05nF 15 0 3.5 120 80 50 100 150 200 250 300 350 400 450 500 DATA RATE (kbps) 3.5 4 4.5 SUPPLY VOLTAGE (V) 5 –25 0 25 50 TEMPERATURE (°C) 75 100 2872 G07 RL = 54Ω 1.5 VCC = 5V VCC = 3.3V 0.5 0 –50 5.5 –25 100 50 75 100 RS485 Driver and Receiver Skew vs Temperature 3.0 VCC = 5V VCC = 3.3V 2.5 OUTPUT LOW 2.0 0 –50 DRIVER 1.5 1.0 RECEIVER OUTPUT HIGH –100 –150 –10 0 25 50 TEMPERATURE (°C) 2872 G06 SKEW (ns) SHORT-CIRCUIT CURRENT (mA) DELAY (ns) 10 0 –50 2.0 2872 G05 150 20 RL = 100Ω 2.5 RS485 Driver Short-Circuit Current vs Short-Circuit Voltage 30 RL = 54Ω 3.0 1.0 85°C 25°C –40°C 3 RL = 100Ω 4.0 140 RS485 Driver Propagation Delay vs Temperature 40 100 4.5 100 VCC = 3.3V, VL = 1.7V VCC = 5V, VL = 1.7V VCC = 3.3V, VL = 3.3V VCC = 5V, VL = 5V 10 1 DATA RATE (Mbps) RS485 Driver Differential Output Voltage vs Temperature BOTH RS485 DRIVERS AND RECEIVERS SWITCHING. 220 Y TIED TO A, Z TIED TO B H/F = 0V 200 DRIVER AND RECEIVER TERMINATION ENABLED 180 20Mbps, C = 100pF ON L Y AND Z TO GND 160 2872 G04 50 TERMINATION DISABLED 2872 G03 VOLTAGE (V) 2.5nF 35 60 0 0.1 5.5 240 VCC = 5V VCC = 3.3V SUPPLY CURRENT (mA) INPUT CURRENT (mA) 40 DRIVER AND RECEIVER TERMINATION ENABLED 80 VCC Supply Current vs Supply Voltage for RS485 at Maximum Data Rate ALL RS232 DRIVERS AND RECEIVERS SWITCHING 45 100 2872 G02 VCC Supply Current vs RS232 Data Rate 50 120 20 3 VCC = 5V VCC = 3.3V ALL RS485 DRIVERS AND 180 RECEIVERS SWITCHING. Y TIED TO A; Z TIED TO B, 160 H/F = 0V, CL = 100pF 140 ON Y AND Z TO GND 40 3.2 2872 G01 10 VCC Supply Current vs RS485 Data Rate 0.5 –5 10 0 5 SHORT-CIRCUIT VOLTAGE (V) 15 2872 G08 0 –50 –25 50 0 25 TEMPERATURE (°C) 75 100 2872 G09 2872f 6 LTC2872 Typical Performance Characteristics RS485 Receiver Propagation Delay vs Temperature 60 50 4 3 2 1 40 –50 –25 50 0 25 TEMPERATURE (°C) 75 0 100 0 2 8 4 6 OUTPUT CURRENT (mA) RS232 Receiver Output Voltage vs Load Current 130 1.6 1.4 4 3 2 1.0 –50 126 0 2 8 4 6 OUTPUT CURRENT (mA) 10 0 25 50 TEMPERATURE (°C) 75 100 RS232 Operation at 500kbps DY DZ 124 Z 122 5V/DIV Y 120 118 RA 116 RB 110 –50 2872 G15 1µs/DIV WRAPPING DATA DOUT LOADS: 5kΩ + 50pF –25 50 0 25 TEMPERATURE (°C) 75 2872 G13 100 2872 G14 RS232 Driver Outputs Enabling and Disabling RS485 Operation at 20Mbps DY VDD and VEE Powering Up DXEN 2V/DIV Y Z 5V/DIV 1V/DIV Y RA 20ns/DIV H/F HIGH Y, Z LOADS: 120Ω (DIFF) + 50pF Z Z 2872 G16 FEN FEN = VL Y 5V/DIV –25 2872 G12 112 5V/DIV VCC = 5V VCC = 3.3V 114 1 0 INPUT LOW 1.2 VCM = –7V VCM = 2V VCM = 12V 128 RESISTANCE (Ω) OUTPUT VOLTAGE (V) INPUT HIGH RS485 Termination Resistance vs Temperature VL = 5V VL = 3.3V VL = 1.7V 5 10 1.8 2872 G11 2872 G10 6 2.0 VL = 5V VL = 3.3V VL = 1.7V 5 OUTPUT VOLTAGE (V) 70 DELAY (ns) 6 VCC = 3.3V, VL = 1.7V VCC = 5V, VL = 1.7V VCC = 3.3V, VL = 3.3V VCC = 5V, VL = 5V RS232 Receiver Input Threshold vs Temperature THRESHOLD VOLTAGE (V) 80 RS485 Receiver Output Voltage vs Load Current 40ns/DIV VDD 5V/DIV FEN = 0V VEE 2872 G17 100µs/DIV 2872 G18 2872f 7 LTC2872 Pin Functions VCC (Pins 1, 21, 31): Input Supply (3.0V to 5.5V). Tie all three pins together and connect 2.2µF capacitor between VCC and GND. VL (Pin 35): Logic Supply (1.7V to 5.5V) for the receiver outputs, driver inputs, and control inputs. This pin should be bypassed to GND with a 0.1µF capacitor if it is not tied to VCC. VL must be less than or equal to VCC for proper operation. VDD (Pin 20): Generated Positive Supply Voltage for RS232 Driver (7V). Connect 2.2µF capacitor between VDD and GND. VEE (Pin 39):Generated Negative Supply Voltage for RS232 Driver (–6.3V). Tie all pins together and connect 2.2µF capacitor between VEE and GND. GND (Pins 5, 18, 27, 34): Ground. Tie all four pins together. CAP (Pin 17): Charge Pump Capacitor for Generated Negative Supply Voltage. Connect a 470nF capacitor between CAP and SW. SW (Pin 19): Switch Pin. Connect 22µH inductor between SW and VCC. A1 (Pin 2): RS485 Differential Receiver #1 Positive Input (Full-Duplex Mode) or RS232 Receiver #1a Input. A2 (Pin 30): RS485 Differential Receiver #2 Positive Input (Full-Duplex Mode) or RS232 Receiver #2a Input. B1 (PIn 3): RS485 Differential Receiver #1 Negative Input (Full-Duplex Mode) or RS232 Receiver #1b Input. B2 (Pin 29): RS485 Differential Receiver #1 Negative Input (Full-Duplex Mode) or RS232 Receiver #2b Input. RA1 (Pin 37): RS485 Differential Receiver #1 Output or RS232 Receiver #1a Output. RA2 (Pin 33): RS485 Differential Receiver #2 Output or RS232 Receiver #2a Output. RB1 (Pin 38): RS232 Receiver #1b Output. RB2 (Pin 32): RS232 Receiver #2b Output. DY1 (Pin 7): RS485 Differential Driver #1 Input or RS232 Driver #1y Input. DY2 (Pin 25): RS485 Differential Driver #2 Input or RS232 Driver #2y Input. DZ1 (Pin 8): RS232 Driver #1z Input. DZ2 (Pin 24): RS232 Driver #2z Input. Y1 (Pin 4): RS485 Differential Driver #1 Positive Output or RS232 Driver #1y Output, RS485 Differential Receiver #1 Positive Input (Half-Duplex Mode). Y2 (Pin 28): RS485 Differential Driver #2 Positive Output or RS232 Driver #2y Output, RS485 Differential Receiver #2 Positive Input (Half-Duplex Mode). Z1 (Pin 6): RS485 Differential Driver #1 Negative Output or RS232 Driver #1z Output, RS485 Differential Receiver #1 Negative Input (Half-Duplex Mode). Z2 (Pin 26): RS485 Differential Driver #2 Negative Output or RS232 Driver #2z Output, RS485 Differential Receiver #2 Negative Input (Half-Duplex Mode). 485/232_1 (Pin 13): Interface Select #1 Input. A logic low enables RS232 mode and a high enables RS485 mode for transceiver #1. The mode determines which transceiver inputs and outputs are accessible at the LTC2872 pins as well as which is controlled by the driver and receiver enable pins. 485/232_2 (Pin 14): Interface Select #2 Input. A logic low enables RS232 mode and a high enables RS485 mode for transceiver #2. The mode determines which transceiver inputs and outputs are accessible at the LTC2872 pins as well as which is controlled by the driver and receiver enable pins. RXEN1 (Pin 9): Receivers #1 Enable. A logic high disables RS232 and RS485 receivers in transceiver #1, leaving their outputs Hi-Z. A logic low enables the RS232 or RS485 receivers in transceiver #1, depending on the state of the Interface Select Input 485/232_1. RXEN2 (Pin 23): Receivers #2 Enable. A logic high disables RS232 and RS485 receivers in transceiver #2, leaving their outputs Hi-Z. A logic low enables the RS232 or RS485 receivers in transceiver #2, depending on the state of the Interface Select Input 485/232_2. 2872f 8 LTC2872 Pin Functions DXEN1 (Pin 10): Drivers #1 Enable. A logic low disables the RS232 and RS485 drivers in transceiver #1, leaving their outputs in a Hi-Z state. A logic high enables the RS232 or RS485 drivers in transceiver #1, depending on the state of the Interface Select Input 485/232_1. DXEN2 (Pin 22): Drivers #2 Enable. A logic low disables the RS232 and RS485 drivers in transceiver #2, leaving their outputs in a Hi-Z state. A logic high enables the RS232 or RS485 drivers in transceiver #2, depending on the state of the Interface Select Input 485/232_2. TE485_1 (Pin 11): RS485 Termination Enable for Transceiver #1. A logic high enables a 120Ω resistor between pins A1 and B1. If DZ1 is also high, a 120Ω resistor is enabled between pins Y1 and Z1. A logic low on TE485_1 opens the resistors, leaving A1/B1 and Y1/Z1 unterminated, independent of DZ1. The differential termination resistors are never enabled in RS232 mode. TE485_2 (Pin 12): RS485 Termination Enable for Transceiver #2. A logic high enables a 120Ω resistor between pins A2 and B2. If DZ2 is also high, a 120Ω resistor is enabled between pins Y2 and Z2. A logic low on TE485_2 opens the resistors, leaving A2/B2 and Y2/Z2 unterminated, independent of DZ2. The differential termination resistors are never enabled in RS232 mode. H/F (Pin 15): RS485 Half-duplex Select Input for Transceivers #1 and #2. A logic low is used for full duplex operation where pins A and B are the receiver inputs and pins Y and Z are the driver outputs. A logic high is used for half duplex operation where pins Y and Z are both the receiver inputs and driver outputs and pins A and B do not serve as the receiver inputs. The impedance on A and B and state of differential termination between A and B is independent of the state of H/F. The H/F pin has no effect on RS232 operation. FEN (Pin 16): Fast Enable. A logic high enables Fast Enable Mode. In fast enable mode the integrated DC/DC converter is active independent of the state of driver, receiver, and termination enable pins allowing faster circuit enable times than are otherwise possible. A logic low disables Fast Enable Mode leaving the state of the DC/DC converter dependent on the state of driver, receiver, and termination enable control inputs. The DC/DC converter powers down only when FEN is low and all drivers, receivers, and terminators are disabled (refer to Table 1). LB (Pin 36): Loopback Enable for Transceivers #1 and #2. A logic high enables Logic Loopback diagnostic mode, internally routing the driver input logic levels to the receiver output pins within the same transceiver. This applies to both RS232 channels as well as the RS485 driver/receiver. The targeted receiver must be enabled for the loopback signal to be available on its output. A logic low disables loopback mode. In loopback mode, signals are not inverted from driver inputs to receiver outputs. 2872f 9 LTC2872 Block Diagram 1.7V TO 5.5V (≤ VCC) 3V TO 5.5V 470nF 22µH 2.2µF 0.1µF 35 21 VL VCC 19 SW 17 CAP 15 H/F 16 FEN 36 LB VDD TRANSCEIVER #1 10 DXEN 9 RXEN1 RT232 CONTROL LOGIC 11 TE485_1 13 485/232_1 VEE PULSE-SKIPPING BOOST REGULATOR f = 1.2MHz GND VCC DRIVERS DY1 2.2µF 39 18 2.2µF RT485 GND 7 20 232 Y1 1 5 4 RT485 485 120Ω 8 DZ1 232 LOOPBACK PATH 125k Z1 6 125k H/F RECEIVERS PORT 1 RT232 232 A1 5k 2 125k 37 RA1 RT485 485 5k 38 22 23 12 14 25 24 33 32 RB1 DXEN2 RXEN2 125k 120Ω B1 3 232 TRANSCEIVER #2 VCC GND TE485_2 485/232_2 Y2 DY2 Z2 DZ2 A2 RA2 B2 RB2 34 31 27 28 26 PORT 2 30 29 GND 2872 BD 2872f 10 LTC2872 Test Circuits Y OR Z Y GND DY OR VL RL + GND OR VL VOD DRIVER Z – RL + DY IOZD485, IOSD485 DRIVER VOC + – Z OR Y VOUT – 2872 F02 2872 F01 Figure 1. RS485 Driver DC Characteristics Figure 2. RS485 Driver Output Short-Circuit Current IIN485 + – A OR B B OR A VIN RIN485 = RECEIVER VIN IIN485 2872 F03 Figure 3. RS485 Receiver Input Current and Resistance (Note 5) tPLHD485 DY Y DY RDIFF DRIVER Z CL VL tPLHD485 0V tSKEWD485 Y, Z ½VOD VOD CL Y-Z 90% 10% 0V 0V tRD485 90% 10% tFD485 2872 F04 Figure 4. RS485 Driver Timing Measurement 2872f 11 LTC2872 test circuits RL Y VL OR GND DY GND OR VCC DXEN ½VL tZLD485, tZLSD485 CL Z RL DXEN CL VCC OR GND VCC 0.5V VOL VOH 0.5V ½VCC Z OR Y 0V tLZD485 ½VCC Y OR Z DRIVER VL ½VL 0V tHZD485 tZHD485, tZHSD485 2872 F05 Figure 5. RS485 Driver Enable and Disable Timing Measurements VAB ±VAB/2 A–B A VCM B 0V tPLHR485 RA RECEIVER CL ±VAB/2 RA 90% 10% tPHLR485 ½VL ½VL tRR485 90% 10% tFR485 tSKEWR485 = tPLHR485 – tPHLR485 –VAB VCC 0V 2872 F06 Figure 6. RS485 Receiver Propagation Delay Measurements (Note 5) RXEN 0V TO 3V 3V TO 0V A B RECEIVER RA RL VL OR GND ½VL VL ½VL tZLR485 ½VL RA 0.5V ½VL RA tZHR485 VL 0.5V CL RXEN 0V tLZR485 tHZR485 VOL VOH 0V 2872 F07 Figure 7. RS485 Receiver Enable and Disable Timing Measurements (Note 5) 2872f 12 LTC2872 test circuits IA RECEIVER TE485 A RTERM = + – VAB IA VL TE485 ½VL ½VL VAB tRTEN485 B 0V 90% IA + – tRTZ485 10% VB 2872 F08 Figure 8. RS485 Termination Resistance and Timing Measurements (Note 5) DRIVER INPUT DRIVER OUTPUT RL DRIVER INPUT CL tPHLD232 ½VL tPLHD232 tF 3V DRIVER INPUT 6V 0V tR 0V –3V SLEW RATE = VL ½VL 0V 3V –3V VOHD VOLD tSKEWD232 = |tPHLD232 – tPLHD232| tF OR tR 2872 F09 Figure 9. RS232 Driver Timing and Slew Rate Measurements DRIVER OUTPUT 0V OR VL DXEN RL DXEN VL ½VL ½VL CL DRIVER OUTPUT 0.5V 5V tZLD232 DRIVER OUTPUT 0V tHZD232 tZHD232 0V tLZD232 5V VOHD 0V 0.5V VOLD 2872 F10 Figure 10. RS232 Driver Enable and Disable Times 2872f 13 LTC2872 test circuits RECEIVER INPUT RECEIVER INPUT RECEIVER OUTPUT 1.5V tPHLR232 CL +3V 1.5V 90% RECEIVER OUTPUT ½VL 10% –3V tPLHR232 ½VL VL 90% 10% tRR232 tFR232 tSKEWR232 = |tPLHR232 – tPHLR232| 0V 2872 F11 Figure 11. RS232 Receiver Timing Measurements RECEIVER OUTPUT RL –3V OR +3V RXEN GND OR VL RXEN VL ½VL ½VL tZHR232 CL RECEIVER OUTPUT 0.5V ½VL tZLR232 RECEIVER OUTPUT 0V tHZR232 0V tLZR232 ½VL VOHR VL 0.5V VOLR 2872 F12 Figure 12. RS232 Receiver Enable and Disable Times 2872f 14 LTC2872 Function Tables Table 1. Shutdown and Fast Enable Modes 485/232_1 AND RXEN1 AND DXEN1 AND 485/232_2 RXEN2 DXEN2 FEN TE485_1 AND TE485_2 H/F LB DC/DC CONVERTER MODE AND COMMENTS 0 X 1 0 0 X X OFF Shutdown: All Main Functions Off 1 X 1 0 0 X X ON Fast-Enable: DC/DC Converter On Only Table 2. Mode Selection Table for a Given Port (FEX = X) 485/232 RXEN DXEN TE485 H/F LB DC/DC CONVERTER 0 0 1 MODE AND COMMENTS X 1 X X 0 ON RS232 Drivers On 0 X X X 0 ON RS232 Receivers On X 1 X X 0 ON RS485 Driver On 1 0 X X X 0 ON RS485 Receiver On 1 X X 1 X X ON RS485 Termination Mode (See Table 7) 1 X X X 0 0 X RS485 Full Duplex Mode 1 X X X 1 0 X RS485 Half Duplex Mode 1 0 X X X 1 ON RS485 Loopback Mode 0 0 X X X 1 ON RS232 Loopback Mode Table 3. RS232 Receiver Mode for a Given Port (485/232 = 0) RXEN RECEIVER INPUT (A, B) CONDITIONS RECEIVER OUTPUTS (RA, RB) RECEIVER INPUTS (A, B) 1 0 X No Fault Hi-Z 125kΩ 0 No Fault 1 5kΩ 0 1 No Fault 0 5kΩ 0 X Thermal Fault Hi-Z 5kΩ Table 4. RS232 Driver Mode for a Given Port (485/232 = 0) DXENX DRIVER INPUT (DY, DZ) CONDITIONS DRIVER OUTPUT (Y, Z) 0 1 X No Fault 125kΩ 0 No Fault 1 1 1 No Fault 0 X X Thermal Fault 125kΩ 2872f 15 LTC2872 function tables Table 5. RS485 Driver Mode for a Given Port (485/232 = 1, TE485 = 0) DXEN DY CONDITIONS Y Z 0 X No Fault 125kΩ 125kΩ 1 0 No Fault 0 1 1 1 No Fault 1 0 X X Thermal Fault 125kΩ 125kΩ Table 6. RS485 Receiver Mode for a Given Port (485/232 = 1, LB = 0) RXEN A–B (NOTE 5) CONDITIONS RA 1 X No Fault Hi-Z 0 < –200mV No Fault 0 0 > 200mV No Fault 1 0 Inputs Open or Shorted Together (DC) No Fault 1 X X Thermal Fault Hi-Z Table 7. RS485 Termination for a Given Port (485/232 = 1) TE485 DZ H/F, LB CONDITIONS R(A TO B) R(Y TO Z) 0 X X No Fault Hi-Z Hi-Z 1 0 X No Fault 120Ω Hi-Z 1 1 X No Fault 120Ω 120Ω X X X Thermal Fault Hi-Z Hi-Z Table 8. RS485 Duplex Control for Given Port (485/232 = 1) H/F RS485 DRIVER OUTPUTS RS485 RECEIVER INPUTS 0 Y, Z A, B 1 Y, Z Y, Z Table 9. Loopback Functions for a Given Port LB RXEN TRANSCEIVER MODE 0 X Not Loopback 1 1 Not Loopback 1 0 Loopback (RA = DY, RB = DZ) 2872f 16 LTC2872 Applications Information Overview The LTC2872 is a flexible multiprotocol transceiver supporting RS485/RS422 and RS232 protocols. It can be powered from a single 3.0V to 5.5V supply with optional logic interface supply as low as 1.7V. An integrated DC/ DC converter provides the positive and negative supply rails needed for RS232 operation. Automatically selected integrated termination resistors for both RS232 and RS485 protocols are included, eliminating the need for external components and switching relays. Both parts include loopback control for self-test and debug as well as logically-switchable half- and full-duplex control of the RS485 bus interface. VCC 3V TO 5.5V VL 1.7V TO VCC C1 470nF L1 22µH C4 2.2µF 21 19 VCC SW VDD C5 0.1µF BOOST REGULATOR VEE 34 GND 18 20 C2 2.2µF 39 GND C3 2.2µF 2872 F13 Figure 13. DC/DC Converter with Required External Components Inductor Selection The LTC2872 features rugged operation with an ESD rating of ±15kV HBM on the receiver inputs and driver outputs, both powered and unpowered. All other pins offer protection exceeding ±4kV. Table 10. Recommended Inductors The on-chip DC/DC converter operates from the VCC input, generating a 7V VDD supply and a charge pumped –6.3V VEE supply, as shown in Figure 13. VDD and VEE power the output stage of the RS232 drivers and are regulated to levels that guarantee greater than ±5V output swing. The DC/DC converter requires a 22µH inductor (L1) and a bypass capacitor (C4) of 2.2µF or larger. The charge pump capacitor (C1) is 470nF and the storage capacitors (C2 and C3) are 2.2µF. Larger storage capacitors up to 4.7µF may be used if C1 and C4 are scaled proportionately. Locate C1-C4 close to their associated pins. CAP 35 VL The LTC2872 offers two ports that can be independently configured as either two RS232 receivers and drivers or one RS485/RS422 receiver and driver depending on the state of its 485/232 pins. Control inputs DXEN and RXEN provide independent control of driver and receiver operation for either RS232 or RS485 transceivers, depending on the selected operating protocol. DC/DC Converter 17 An inductor with a value of 22µH ±20% is required. It must have a saturation current (ISAT) rating of at least 200mA and a DCR (copper wire resistance) of less than 1.3Ω. Some small inductors meeting these requirements are listed in Table 10. PART NUMBER BRC2016T220M CBC2518T220M MAX L ISAT DCR (µH) (mA) (Ω) SIZE (mm) MANUFACTURER 22 22 310 320 1.3 1.0 2 × 1.6 × 1.6 Taiyo Yuden 2.5 × 1.8 × 1.8 t-yuden.com LQH32CN220K53 22 250 0.92 3.2 × 2.5 × 1.6 Murata murata.com Capacitor Selection The small size of ceramic capacitors makes them ideal for the LTC2872. Use X5R or X7R dielectric types; their ESR is low and they retain their capacitance over relatively wide voltage and temperature ranges. Use a voltage rating of at least 10V. Bypass capacitor C5 on the logic supply pin can be omitted if VL is connected to VCC. See the VL Logic Supply section for more details about the VL logic supply. 2872f 17 LTC2872 Applications Information Inrush Current and Supply Overshoot Precaution In certain applications fast supply slew rates are generated when power is connected. If VCC’s voltage is greater than 4.5V and its rise time is faster than 10μs, the pins VDD and SW can exceed their Absolute Maximum values during start-up. When supply voltage is applied to VCC, the voltage difference between VCC and VDD generates inrush current flowing through inductor L1 and capacitors C1 and C2. The peak inrush current must not exceed 2A. To avoid this condition, add a 1Ω resistor as shown in Figure 14. This precaution is not relevant for supply voltages below 4.5V or rise times longer than 10μs. 5V 0V ≤10µs R1 1Ω 1/8W C4 2.2µF INRUSH CURRENT 19 SW 17 CAP 21 VDD The RS485 driver provides full RS485/RS422 compatibility. When enabled, if DI is high, Y–Z is positive. When the driver is disabled, Y and Z output resistance is greater than 96k (typically 125k) to ground over the entire common mode range of –7V to 12V. This resistance is equivalent to the input resistance on these lines when the driver is configured in half-duplex mode and Y and Z act as the RS485 receiver inputs. The RS232 and RS485 driver outputs are protected from short circuits to any voltage within the Absolute Maximum range ±15V. The maximum current in this condition is 90mA for the RS232 driver and 250mA for the RS485 driver. VCC 20 RS485 Driver Driver Overvoltage and Overcurrent Protection C1 470nF L1 22µH by more than 1V for proper operation. Logic input pins do not have internal biasing devices to pull them up or down. They must be driven high or low to establish valid logic levels; do not float. 18 GND 2872 F14 C2 2.2µF Figure 14. Supply Current Overshoot Protection for Input Supplies of 4.5V of Higher VL Logic Supply A separate logic supply pin VL allows the LTC2872 to interface with any logic signal from 1.7V to 5.5V. All logic I/Os use VL as their high supply. For proper operation, VL should not be greater than VCC. During power-up, if VL is higher than VCC, the device will not be damaged, but behavior of the device is not guaranteed. If VL is not connected to VCC, bypass VL with a 0.1µF capacitor. RS232 and RS485 driver outputs are undriven and the RS485 termination resistors are disabled when VL or VCC is grounded or VCC is disconnected. Although all logic input pins reference VL as their high supply, they can be driven up to 7V, independent of VL and VCC, with the exception of FEN, which must not exceed VL If an RS485 driver output is shorted to a voltage greater than VCC, when active high, positive current of about 100mA can flow from the driver output back to VCC. If the system power supply or loading cannot sink this excess current, clamp VCC to GND with a Zener diode (e.g., 5.6V, 1W, 1N4734) to prevent an overvoltage condition on VCC. All devices also feature thermal shutdown protection that disables the drivers, receivers, and RS485 terminators in case of excessive power dissipation (see Note 6). RS485 Balanced Receiver with Full Failsafe Support The LTC2872 RS485 receiver has a differential threshold voltage that is about 80mV for signals that are rising and –80mV for signals that are falling, as illustrated in Figure 15. If a differential input signal lingers in the window between these thresholds for more than about 2µs, the rising threshold changes from 80mV to –50mV, while the falling threshold remains at –80mV. Thus, differential inputs that are shorted, open, or terminated but not driven for more than 2µs produce a high on the receiver output, indicating a failsafe condition. 2872f 18 LTC2872 Applications Information RA RISING THRESHOLD SHIFTS IF SIGNAL IS IN WINDOW > ~2µs TO SUPPORT FAILSAFE –80mV –50mV 0V VAB (NOTE 5) 80mV 2872 F15 Figure 15. RS485 Receiver Input Threshold Characteristics with Typical Values Shown The benefit of this dual threshold architecture is that it supports full failsafe operation yet offers a balanced threshold, centered on 0V, for normal data signals. This balance preserves duty cycle for small input signals with heavily slewed edges, typical of what might be seen at the end of a very long cable. This performance is highlighted in Figure 16, where a signal is driven through 4000 feet of CAT5e cable at 3Mbps. Even though the differential signal peaks at just over 100mV and is heavily slewed, the output maintains a nearly perfect signal with almost no duty cycle distortion. B 0.1V/DIV A 0.1V/DIV 5V/DIV lines, which establishes a logic-high state when all the transmitters on the network are disabled. The values of the biasing resistors depend on the number and type of transceivers on the line and the number and value of terminating resistors. Therefore, the values of the biasing resistors must be customized to each specific network installation, and may change if nodes are added to or removed from the network. The internal failsafe feature of the LTC2872 eliminates the need for external network biasing resistors provided they are used in a network of transceivers with similar internal failsafe features. This also allows the network to support a high number of nodes, up to 256, by eliminating the bias resistor loading. The LTC2872 transceivers will operate correctly on biased, unbiased, or under-biased networks. Receiver Outputs The RS232 and RS485 receiver outputs are internally driven high (to VL) or low (to GND) with no external pull-up needed. When the receivers are disabled, the output pin becomes Hi-Z with leakage of less than ±5μA for voltages within the VL supply range. RS485 Receiver Input Resistance (A-B) RA 200ns/DIV 2872 F16 Figure 16. A 3Mbps Signal Driven Down 4000ft of CAT5e Cable. Top Traces: Received Signals After Transmission Through Cable; Middle Trace: Math Showing Differences of Top Two Signals; Bottom Trace: Receiver Output An additional benefit of the balanced architecture is excellent noise immunity due to the wide effective differential input signal hysteresis of 160mV for signals transitioning through the window region in less than 2μs. Increasingly slower signals will have increasingly less effective hysteresis, limited by the DC failsafe hysteresis of about 30mV. RS485 Biasing Network Not Required RS485 networks are often biased with a resistive divider to generate a differential voltage of ≥200mV on the data The RS485 receiver input resistance from A or B to GND (Y or Z to GND in half-duplex mode with driver disabled) is greater than 96k (typically 125k) when the integrated termination is disabled. This permits up to a total of 256 receivers per system without exceeding the RS485 receiver loading specification. The input resistance of the receiver is unaffected by enabling/disabling the receiver or whether the part is in half-duplex, full-duplex, loopback mode, or even unpowered. The equivalent input resistance looking into the RS485 receiver pins is shown in Figure 17. 125k A 60Ω TE485 125k 60Ω B 2872 F17 Figure 17. Equivalent RS485 Receiver Input Resistance Into A and B (Note 5) 2872f 19 LTC2872 Applications Information Selectable RS485 Termination Proper cable termination is important for good signal fidelity. When the cable is not terminated with its characteristic impedance, reflections cause waveform distortion. The LTC2872 offers integrated switchable 120Ω termination resistors between the differential receiver inputs and also between the differential driver outputs. This provides the advantage of being able to easily change, through logic control, the proper line termination for correct operation when configuring transceiver networks. Termination should be enabled on transceivers positioned at both ends of a network bus. Termination on the driver nodes is important for cases where the driver is disabled but there is communication on the connecting bus from another node. Driver termination across Y and Z can be disabled independently from the termination across A and B by setting DZ low. See Table 7 for details. The termination resistance is maintained over the entire RS485 common mode range of –7V to 12V as shown in Figure 18. The voltage across pins with the terminating resistor enabled should not exceed 6V as indicated in the Absolute Maximum Ratings table. 126 VCC = 5.0V VCC = 3.3V Logic Loopback A loopback mode connects the driver inputs to the receiver outputs (noninverting) for self test. This applies to both RS232 and RS485 transceivers. Loopback mode is entered when the LB pin is set to a logic-high and the relevant receiver is enabled. In loopback mode, the drivers function normally. They can be disabled with output in a Hi-Z state or left enabled to allow loopback testing in normal operation. Loopback works in half- or full-duplex modes and does not affect the termination resistors. RS485 Cable Length vs Data Rate Many factors contribute to the maximum cable length that can be used for for RS485 or RS422 communication, including driver transition times, receiver threshold, duty cycle distortion, cable properties and data rate. A typical curve of cable length versus maximum data rate is shown in Figure 19. Various regions of this curve reflect different performance limiting factors in data transmission. 122 10k 120 118 116 –10 –5 0 5 VOLTAGE (V) 10 15 2872 F18 CABLE LENGTH (FT) RESISTANCE (Ω) 124 the differential receiver inputs. With the H/F pin set to a logic-high, the Y and Z pins serve as the differential inputs. In either configuration, the RS485 driver outputs are always on Y and Z. The impedance looking into the A and B pins is not affected by H/F control, including the differential termination resistance. The H/F control does not affect RS232 operation. 1k LTC2872 MAX DATA RATE 100 Figure 18. Typical Resistance of the Enabled RS485 Terminator vs Common Mode Voltage of A and B RS485 Half- and Full-Duplex Control The LTC2872 is equipped with a control to change the RS485 transceiver operation from full-duplex to half-duplex. With the H/F pin set to a logic-low, the A and B pins serve as RS485/RS422 MAX DATA RATE 10 10k 100k 1M 10M DATA RATE (bps) 100M 2872 F19 Figure 19. Cable Length vs Data Rate (RS485/RS422 Standard Shown in Vertical Solid Line) 2872f 20 LTC2872 Applications Information At frequencies below 100kbps, the maximum cable length is determined by DC resistance in the cable. In this example, a cable longer than 4000ft will attenuate the signal at the far end to less than what can be reliably detected by the receiver. For data rates above 100kbps, the capacitive and inductive properties of the cable begin to dominate this relationship. The attenuation of the cable is frequency and length dependent, resulting in increased rise and fall times at the far end of the cable. At high data rates or long cable lengths, these transition times become a significant part of the signal bit time. Jitter and intersymbol interference aggravate this so that the time window for capturing valid data at the receiver becomes impossibly small. The boundary at 20Mbps in Figure 19 represents the guaranteed maximum operating rate of the LTC2872. The dashed vertical line at 10Mbps represents the specified maximum data rate in the RS485 standard. This boundary is not a limit, but reflects the maximum data rate that the specification was written for. It should be emphasized that the plot in Figure 19 shows a typical relation between maximum data rate and cable length. Results with the LTC2872 will vary, depending on cable properties such as conductor gauge, characteristic impedance, insulation material, and solid versus stranded conductors. Layout Considerations All VCC pins must be connected together and all ground pins must be connected together on the PC board with very low impedance traces or dedicated planes. A 2.2µF, or larger, bypass capacitor should be placed less than 0.7cm away from VCC Pin 21. This VCC pin, as well as GND Pin 18, mainly service the DC/DC converter. Additional bypass capacitors of 0.1µF or larger, can be added to VCC Pins 1 and 31 if the traces back to the 2.2µF capacitor are indirect or narrow. These VCC pins mainly service the transceivers #1 and #2, respectively. Table 11 summarizes the bypass capacitor requirements. The capacitors listed in the table should be placed closest to their respective supply and ground pin. Table 11. Bypass Capacitor Requirements CAPACITOR SUPPLY (PIN) RETURN (PIN) COMMENT 2.2µF VCC (21) GND (18) Required 2.2 µF VDD (20) GND (18) Required 2.2uF VEE (39) GND (18) Required 0.1µF VL (35) GND (34) Required* 0.1µF VCC (1) GND (5) Optional 0.1µF VCC (31) GND (27) Optional * If VL is not connected to VCC. Place the charge pump capacitor, C1, directly adjacent to the SW and CAP pins, with no more than one centimeter of total trace length to maintain low inductance. Close placement of the inductor, L1, is of secondary importance compared to the placement of C1 but should include no more than two centimeters of total trace length. The PC board traces connected to high speed signals A/B and Y/Z should be symmetrical and as short as possible to minimize capacitive imbalance and to maintain good differential signal integrity. To minimize capacitive loading effects, the differential signals should be separated by more than the width of a trace and should not be routed on top of each other if they are on different signal planes. Care should be taken to route outputs away from any sensitive inputs to reduce feedback effects that might cause noise, jitter, or even oscillations. For example, DI and A/B should not be routed near the driver or receiver outputs. 2872f 21 LTC2872 Typical Applications VCC = 3V to 5.5V, VL = 1.7V to VCC. Logic input pins not shown are tied to a valid logic state. External components necessary for operation are not shown. VL VL LTC2872 LTC2872 485/232_1 485/232_2 LB DY1 Y1 DZ1 Z1 RA1 A1 RB1 B1 485/232_2 DY1 485/232_1 A1 RB1 B1 DY2 Z2 RA2 A2 DY2 RB2 DZ2 Z2 RA2 A2 RA2 B2 B2 H/F LB GND Y1 DY1 Z1 Z1 A1 A1 RA1 B1 B1 Y2 Y2 DY2 Y2 DZ2 485/232_1 485/232_2 Y1 DY1 Z1 RB1 LTC2872 485/232_2 H/F LB GND Y1 DZ1 Y2 LTC2872 485/232_1 H/F LB GND RA1 DY2 VL RB2 Z2 Z2 A2 A2 RA2 B2 B2 2872 F20 PORT 1: RS232 PORT 2: RS232 PORT 1: RS232 PORT 2: RS485 PORT 1: RS485 PORT 2: RS232 PORT 1: RS485 PORT 2: RS485 Figure 20. LTC2872 in Various Basic Port Configurations VL VL LTC2872 LB 485/232_2 485/232_1 RXEN1 RXEN2 H/F GND DY1 Y1 DZ1 Z1 RA1 A1 VL H/F TE485_1 TE485_2 485/232_1 485/232_2 DZ1 DZ2 LTC2872 LB GND TE485_1 TE485_2 DZ1 485/232_1 485/232_2 LTC2872 DZ2 H/F LB GND Y1 Y1 RB1 B1 DY1 RA1 120Ω 120Ω B1 RA2 Z2 Y2 DY2 A2 B2 2872 F21 Figure 21. Loopback in RS232 and RS485 Modes RA2 120Ω 120Ω Z1 A1 Y2 DY2 DY1 RA1 120Ω A2 2872 F22 Figure 22. Half-Duplex RS485 Mode with Driver and Receiver Line Termination on Each Port B1 Y2 DY2 Z2 Z2 120Ω B2 Z1 A1 A2 RA2 120Ω B2 2872 F23 Figure 23. Full-Duplex RS485 Mode with Driver and Receiver Line Termination on Port 1, and ReceiverOnly Termination on Port 2 2872f 22 LTC2872 typical Applications CC = 3V to 5.5V, VL = 1.7V to VCC. Logic input pins not shown are tied to a valid logic V state. External components necessary for operation are not shown. ½ LTC2872 VL H/F TE485 ½ LTC2872 ½ LTC2872 120Ω 120Ω VL VL TE485 DZ H/F TE485 DZ H/F 2872 F24 Figure 24. Typical RS485 Half Duplex Network ½ LTC2872 TE485 H/F MASTER SLAVE ½ LTC2872 ½ LTC2872 120Ω 120Ω 120Ω VL TE485 DZ H/F VL TE485 DZ H/F 2872 F25 Figure 25. Typical RS485 Full Duplex Network 2872f 23 LTC2872 typical Applications VCC = 3V to 5.5V, VL = 1.7V to VCC. Logic input pins not shown are tied to a valid logic state. External components necessary for operation are not shown. LTC2872 H/F S3 Y1 RS485 INTERFACE Z1 INPUT1 RA1 OUTPUT A1 RXEN1 S1 H/F B1 INPUT2 Y2 Z2 INPUT3 RA2 A2 RXEN2 S2 B2 INPUT4 2872 F26 S1 S2 S3 SELECTED INPUT 0 1 1 INPUT1 0 1 0 INPUT2 1 0 1 INPUT3 1 0 0 INPUT4 1 1 X NONE/Hi-Z 0 0 X INVALID Figure 26. RS485 Receiver with 4-Way Selectable Inputs 2872f 24 LTC2872 typical Applications CC = 3V to 5.5V, VL = 1.7V to VCC. Logic input pins not shown are tied to a valid logic V state. External components necessary for operation are not shown. LTC2872 OUT1 S1 OUT2 S2 LTC2872 RA1 A1 RS232 INPUT RXEN1 RB2 OUT2 RXEN2 RS232 INPUT RIN –OR– A2 B1 RXEN1 S1 RIN RA2 RB1 OUT1 B2 RXEN2 S2 2872 F27 S1 S2 RIN ACTIVE OUTPUT 0 1 5k OUT1 1 0 5k OUT2 1 1 62.5k NONE (Hi-Z) 0 0 2.5k* OUT1, OUT2 * DOES NOT MEET RS232 SPECIFICATIONS Figure 27. Sharing RS232 Receiver Inputs 3V TO 5.5V 1.7V TO VCC VCC LTC2872 VL µP LOGIC LEVEL SIGNALS LINE LEVEL SIGNALS RS232 AND/OR RS485 GND 2872 F28 Figure 28. Low Voltage Microprocessor Interface 2872f 25 LTC2872 typical Applications VCC = 3V to 5.5V, VL = 1.7V to VCC. Logic input pins not shown are tied to a valid logic state. External components necessary for operation are not shown. RA1 LTC2872 DY2 Y2 RS232 IN A1 RS232 OUT Y1 Z2 RS485 OUT A2 120Ω DY1 B2 RS485 IN RA2 2872 F29 Figure 29. RS232 ↔ RS485 Conversion RA1 LTC2872 DY2 Y2 A1 B1 120Ω 120Ω A2 Y1 Z1 Z2 120Ω 120Ω DY1 B2 RA2 2872 F29 Figure 30. RS485 Repeater 2872f 26 LTC2872 Package Description Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings. UHF Package 38-Lead Plastic QFN (5mm × 7mm) (Reference LTC DWG # 05-08-1701 Rev C) 0.70 ± 0.05 5.50 ± 0.05 5.15 ± 0.05 4.10 ± 0.05 3.00 REF 3.15 ± 0.05 PACKAGE OUTLINE 0.25 ± 0.05 0.50 BSC 5.5 REF 6.10 ± 0.05 7.50 ± 0.05 RECOMMENDED SOLDER PAD LAYOUT APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED 5.00 ± 0.10 0.75 ± 0.05 PIN 1 NOTCH R = 0.30 TYP OR 0.35 × 45° CHAMFER 3.00 REF 37 0.00 – 0.05 38 0.40 ±0.10 PIN 1 TOP MARK (SEE NOTE 6) 1 2 5.15 ± 0.10 5.50 REF 7.00 ± 0.10 3.15 ± 0.10 (UH) QFN REF C 1107 0.200 REF 0.25 ± 0.05 0.50 BSC R = 0.125 TYP R = 0.10 TYP BOTTOM VIEW—EXPOSED PAD NOTE: 1. DRAWING CONFORMS TO JEDEC PACKAGE OUTLINE M0-220 VARIATION WHKD 2. DRAWING NOT TO SCALE 3. ALL DIMENSIONS ARE IN MILLIMETERS 4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.20mm ON ANY SIDE 5. EXPOSED PAD SHALL BE SOLDER PLATED 6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION ON THE TOP AND BOTTOM OF PACKAGE 2872f 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. 27 LTC2872 Typical Application 5V 2.2µF 1.8V 0.1µF VCC 3.3V 470nF 22µH SW 2.2µF CAP VL 485/232_2 485/232_1 TE485_2 TE485_1 LB LTC2872 DZ1 GND H/F RS485 Z1 CAT5e CABLE A1 RA1 SW CAP DZ2 LB GND Y1 120Ω Z1 1.8V INTERFACE VCC VL 485/232_1 485/232_2 LTC2872 TE485_1 TE485_2 DZ1 H/F Y1 DY1 470nF 22µH 120Ω A1 DYI RA1 120Ω 120Ω B1 B1 DY2 Y2 Y2 DZ2 Z2 Z2 RA2 A2 3.3V INTERFACE DY2 RS232 A2 RA2 120Ω RA2 A2 VDD VEE B2 VDD VEE 2872 F31 2.2µF 2.2µF 2.2µF 2.2µF Figure 31. LTC2872 on Left: RS485 Half-Duplex and Terminated, Plus RS232. LTC2872 on Right: Dual RS485 Half-Duplex and Terminated. All External Components Shown Related Parts PART NUMBER DESCRIPTION COMMENTS LTC2870/LTC2871 RS232/RS485 Multiprotocol Transceivers with Integrated Termination 3V to 5.5V Supply, Automatic Selection of Termination Resistors, Duplex Control, Logic Supply Pin, ±26kV ESD LTC1334 Single 5V RS232/RS485 Multiprotocol Transceiver Dual Port, Single 5V Supply, Configurable, ±10kV ESD LTC1387 Single 5V RS232/RS485 Multiprotocol Transceiver Single Port, Configurable LTC2801/LTC2802/ LTC2803/LTC2804 1.8V to 5.5V RS232 Single and Dual Transceivers Up to 1Mbps, ±10kV ESD, Logic Supply Pin, Tiny DFN Packages LTC2854/LTC2855 3.3V 20Mbps RS485 Transceiver with Integrated Switchable Termination 3.3V Supply, Integrated, Switchable, 120Ω Termination Resistor, ±25kV ESD LTC2859/LTC2861 20Mbps RS485 Transceiver with Integrated Switchable Termination 5V Supply, Integrated, Switchable, 120Ω Termination Resistor, ±15kV ESD LTM2881 Complete Isolated RS485/RS422 μModule® Transceiver + Power 20Mbps, 2500VRMS Isolation with Integrated DC/DC Converter, Integrated Switchable 120Ω Termination Resistor, ±15kV ESD LTM2882 Dual Isolated RS232 µModule Transceiver + Power 1Mbps, 2500VRMS Isolation with Integrated DC/DC Converter, ±10kV ESD 2872f 28 Linear Technology Corporation LT 0312 • PRINTED IN USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com  LINEAR TECHNOLOGY CORPORATION 2012