® R EC TR909 DLC/FLC SLIC with Low Power Standby Part Number Information HC5513BIP -40 to 85 FN3963.12 • DI Monolithic High Voltage Process The HC5513 is fabricated in a High Voltage Dielectrically Isolated (DI) Bipolar Process that eliminates leakage currents and device latch-up problems normally associated with Junction Isolated (JI) ICs. The elimination of the leakage currents results in improved circuit performance for wide temperature extremes. The latch free benefit of the DI xxprocess guarantees operation under adverse transient conditions. This process feature makes the HC5513 ideally suited for use in harsh outdoor environments. TEMP. RANGE (oC) August 2003 Features The HC5513 is a subscriber line interface circuit which is interchangeable with Ericsson’s PBL3764 for distributed central office applications. Enhancements include immunity to circuit latch-up during hot plug and absence of false signaling in the presence of longitudinal currents. PART NUMBER HC5513 UCT ROD CEMENT P E T A O LE EPL OB S NDE D R 515 MME Sheet OData HC5 • Programmable Current Feed (20mA to 60mA) • Programmable Loop Current Detector Threshold and Battery Feed Characteristics • Ground Key and Ring Trip Detection • Compatible with Ericsson’s PBL3764 • Thermal Shutdown • On-Hook Transmission • Wide Battery Voltage Range (-24V to -58V) • Low Standby Power • Meets TR-NWT-000057 Transmission Requirements • -40oC to 85oC Ambient Temperature Range Applications PACKAGE 22 Ld PDIP PKG. DWG. # • Digital Loop Carrier Systems • Pair Gain E22.4 • Fiber-In-The-Loop ONUs • POTS • Wireless Local Loop • PABX • Hybrid Fiber Coax • Related Literature - AN9537, Operation of the HC5513/26 Evaluation Board Block Diagram RINGRLY DT DR RING RELAY DRIVER 4-WIRE INTERFACE VF SIGNAL PATH RING TRIP DETECTOR VTX RSN TIP RING HPT 2-WIRE INTERFACE LOOP CURRENT DETECTOR E0 E1 HPR GROUND KEY DETECTOR DIGITAL MULTIPLEXER C1 C2 VBAT VCC VEE DET BIAS RD AGND RDC BGND RSG 1 CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures. 1-888-INTERSIL or 321-724-7143 | Intersil (and design) is a registered trademark of Intersil Americas Inc. Copyright © Intersil Americas Inc. 2003. All Rights Reserved All other trademarks mentioned are the property of their respective owners. HC5513 Absolute Maximum Ratings Thermal Information Operating Temperature Range . . . . . . . . . . . . . . . . -40oC to 110oC Power Supply (-40oC ≤ TA ≤ 85oC) Supply Voltage VCC to GND . . . . . . . . . . . . . . . . . . . . 0.5V to 7V Supply Voltage VEE to GND. . . . . . . . . . . . . . . . . . . . . -7V to 0.5V Supply Voltage VBAT to GND . . . . . . . . . . . . . . . . . . . -70V to 0.5V Ground Voltage between AGND and BGND . . . . . . . . . . . . . -0.3V to 0.3V Relay Driver Ring Relay Supply Voltage . . . . . . . . . . . . . . . . . . . . . . 0V to 20V Ring Relay Current. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50mA Ring Trip Comparator Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VBAT to 0V Input Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -5mA to 5mA Digital Inputs, Outputs (C1, C2, E0, E1, DET) Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .0V to VCC Output Voltage (DET Not Active) . . . . . . . . . . . . . . . . . .0V to VCC Output Current (DET) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5mA Tipx and Ringx Terminals (-40oC ≤ TA ≤ 85oC) Tipx or Ringx Voltage, Continuous (Referenced to GND) .VBAT to 2V Tipx or Ringx, Pulse < 10ms, TREP > 10s . . . . . .VBAT -20V to 5V Tipx or Ringx, Pulse < 10µs, TREP > 10s . . . . VBAT -40V to 10V Tipx or Ringx, Pulse < 250ns, TREP > 10s. . . . VBAT -70V to 15V Tipx or Ringx Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70mA ESD Rating Human Body Model (Per MIL-STD-883 Method 3015.7) . . . .500V Thermal Resistance (Typical, Note 1) θJAoC/W 22 Lead PDIP Package . . . . . . . . . . . . . . . . . . . . . . 53 Continuous Dissipation at 70oC 22 Lead PDIP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1.5W Package Power Dissipation at 70oC, t < 100ms, tREP > 1s 22 Lead PDIP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4W Derate above . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .70oC Plastic DIP Package. . . . . . . . . . . . . . . . . . . . . . . . . . 18.8mW/oC Maximum Junction Temperature Range . . . . . . . . . -40oC to 150oC Maximum Storage Temperature Range . . . . . . . . . . -65oC to 150oC Die Characteristics Gate Count . . . . . . . . . . . . . . . . . . . . . . .543 Transistors, 51 Diodes CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. NOTE: 1. θJA is measured with the component mounted on an evaluation PC board in free air. Typical Operating Conditions These represent the conditions under which the part was developed and are suggested as guidelines. PARAMETER CONDITIONS Case Temperature MIN TYP MAX UNITS -40 - 100 oC - 5.25 V VCC with Respect to AGND -40oC to 85oC 4.75 VEE with Respect to AGND -40oC to 85oC -40oC to 85oC -5.25 - -4.75 V -58 - -24 V VBAT with Respect to BGND TA = -40oC to 85oC, VCC = 5V ±5%, VEE = -5V ±5%, VBAT = -28V, AGND = BGND = 0V, RDC1 = RDC2 = 41.2kΩ, RD = 39kΩ, RSG = ∞, RF1 = RF2 = 0Ω, CHP = 10nF, CDC = 1.5µF, ZL = 600Ω. Electrical Specifications PARAMETER CONDITIONS Overload Level 1% THD, ZL = 600Ω, (Note 2, Figure 1) Longitudinal Impedance (Tip/Ring) 0 < f < 100Hz (Note 3, Figure 2) MIN TYP MAX UNITS 3.1 - - VPEAK - 20 35 Ω/Wire AT TIP 5 1VRMS TIP 5 RL 600Ω VTX 21 0 < f < 100Hz EL C RT 600kΩ VTRO IDCMET 23mA RRX RING 6 RSN 19 RT 600kΩ 2.16µF 300Ω ERX 300kΩ FIGURE 1. OVERLOAD LEVEL (TWO-WIRE PORT) 2 VT 300Ω VTX 21 VR AR RRX RING 6 LZT = VT/AT RSN 19 300kΩ LZR = VR/AR FIGURE 2. LONGITUDINAL IMPEDANCE HC5513 TA = -40oC to 85oC, VCC = 5V ±5%, VEE = -5V ±5%, VBAT = -28V, AGND = BGND = 0V, RDC1 = RDC2 = 41.2kΩ, RD = 39kΩ, RSG = ∞, RF1 = RF2 = 0Ω, CHP = 10nF, CDC = 1.5µF, ZL = 600Ω. (Continued) Electrical Specifications PARAMETER CONDITIONS MIN TYP MAX UNITS LONGITUDINAL CURRENT LIMIT (TIP/RING) Off-Hook (Active) No False Detections, (Loop Current), LB > 45dB (Note 4, Figure 3A) - - 20 mAPEAK /Wire On-Hook (Standby), RL = ∞ No False Detections (Loop Current) (Note 5, Figure 3B) - - 5 mAPEAK /Wire 368Ω 368Ω A TIP 5 RSN 19 A 2.16µF 39kΩ C EL RDC1 41.2kΩ RD -5V 2.16µF A 368Ω RDC2 CDC RING RDC 17 41.2kΩ 6 DET 1.5µF C TIP 5 RSN 19 39kΩ EL RD RDC1 41.2kΩ RDC2 RDC RING 17 41.2kΩ 6 DET CDC -5V 2.16µF C A 368Ω FIGURE 3A. OFF-HOOK 1.5µF FIGURE 3B. ON-HOOK FIGURE 3. LONGITUDINAL CURRENT LIMIT OFF-HOOK LONGITUDINAL BALANCE Longitudinal to Metallic IEEE 455 - 1985, RLR, RLT = 368Ω , 0.2kHz < f < 4.0kHz (Note 6, Figure 4) 55 70 - dB Longitudinal to Metallic RLR , RLT = 300Ω, 0.2kHz < f < 4.0kHz (Note 6, Figure 4) 55 70 - dB Metallic to Longitudinal FCC Part 68, Para 68.310 0.2kHz < f < 1.0kHz 50 55 - dB 1.0kHz < f < 4.0kHz (Note 7) 50 55 - dB Longitudinal to 4-Wire 0.2kHz < f < 4.0kHz (Note 8, Figure 4) 55 70 - dB Metallic to Longitudinal RLR , RLT = 300Ω, 0.2kHz < f < 4.0kHz (Note 9, Figure 5) 50 55 - dB 4-Wire to Longitudinal 0.2kHz < f < 4.0kHz (Note 10, Figure 5) 50 55 - dB RLT RLT TIP 5 EL VTX 21 C 2.16µF RT 600kΩ VTR 2.16µF VTX RRX RING 6 RSN 19 300kΩ FIGURE 4. LONGITUDINAL TO METALLIC AND LONGITUDINAL TO 4-WIRE BALANCE 3 VTX 21 RT 600kΩ ETR C VL RLR TIP 5 300Ω RRX RLR 300Ω RING 6 RSN 19 ERX 300kΩ FIGURE 5. METALLIC TO LONGITUDINAL AND 4-WIRE TO LONGITUDINAL BALANCE HC5513 TA = -40oC to 85oC, VCC = 5V ±5%, VEE = -5V ±5%, VBAT = -28V, AGND = BGND = 0V, RDC1 = RDC2 = 41.2kΩ, RD = 39kΩ, RSG = ∞, RF1 = RF2 = 0Ω, CHP = 10nF, CDC = 1.5µF, ZL = 600Ω. (Continued) Electrical Specifications PARAMETER CONDITIONS MIN TYP MAX UNITS 0.2kHz to 0.5kHz (Note 11, Figure 6) 25 - - dB 0.5kHz to 1.0kHz (Note 11, Figure 6) 27 - - dB 1.0kHz to 3.4kHz (Note 11, Figure 6) 23 - - dB Active, IL = 0 - -4 - V Standby, IL = 0 - <0 - V Active, IL = 0 - -24 - V Standby, IL = 0 - >-28 - V 2-Wire Return Loss CHP = 20nF TIP IDLE VOLTAGE RING IDLE VOLTAGE 4-WIRE TRANSMIT PORT (VTX) Overload Level (ZL > 20kΩ, 1% THD) (Note 12, Figure 7) 3.1 - - VPEAK Output Offset Voltage EG = 0, ZL = ∞, (Note 13, Figure 7) -60 - 60 mV Output Impedance (Guaranteed by Design) 0.2kHz < f < 03.4kHz - 5 20 Ω 2- to 4-Wire (Metallic to VTX) Voltage Gain 0.3kHz < f < 03.4kHz (Note 14, Figure 7) 0.98 1.0 1.02 V/V ZD 2.16µF TIP 5 R VTX 21 RL 600Ω VM RT 600kΩ VS R EG ZIN RLR TIP 5 C VTX 21 VTR RT 600kΩ IDCMET 23mA RSN 19 RING 6 300kΩ FIGURE 6. TWO-WIRE RETURN LOSS ZL RRX RRX RING 6 VTXO VTX RSN 19 300kΩ FIGURE 7. OVERLOAD LEVEL (4-WIRE TRANSMIT PORT), OUTPUT OFFSET VOLTAGE, 2-WIRE TO 4-WIRE VOLTAGE GAIN AND HARMONIC DISTORTION 4-WIRE RECEIVE PORT (RSN) DC Voltage IRSN = 0mA - 0 - V RX Sum Node Impedance (Guaranteed by Design) 0.3kHz < f < 3.4kHz - - 20 Ω Current Gain-RSN to Metallic 0.3kHz < f < 3.4kHz (Note 15, Figure 8) 980 1000 1020 Ratio 2-Wire to 4-Wire 0dBm at 1.0kHz, ERX = 0V 0.3kHz < f < 3.4kHz (Note 16, Figure 9) -0.2 - 0.2 dB 4-Wire to 2-Wire 0dBm at 1.0kHz, EG = 0V 0.3kHz < f < 3.4kHz (Note 17, Figure 9) -0.2 - 0.2 dB 4-Wire to 4-Wire 0dBm at 1.0kHz, EG = 0V 0.3kHz < f < 3.4kHz (Note 18, Figure 9) -0.2 - 0.2 dB FREQUENCY RESPONSE (OFF-HOOK) 4 HC5513 TA = -40oC to 85oC, VCC = 5V ±5%, VEE = -5V ±5%, VBAT = -28V, AGND = BGND = 0V, RDC1 = RDC2 = 41.2kΩ, RD = 39kΩ, RSG = ∞, RF1 = RF2 = 0Ω, CHP = 10nF, CDC = 1.5µF, ZL = 600Ω. (Continued) Electrical Specifications PARAMETER CONDITIONS MIN TYP MAX UNITS 2-Wire to 4-Wire 0dBm, 1kHz (Note 19, Figure 9) -0.2 - 0.2 dB 4-Wire to 2-Wire 0dBm, 1kHz (Note 20, Figure 9) -0.2 - 0.2 dB 2-Wire to 4-Wire -40dBm to +3dBm (Note 21, Figure 9) -0.1 - 0.1 dB 2-Wire to 4-Wire -55dBm to -40dBm (Note 21, Figure 9) - ±0.03 - dB 4-Wire to 2-Wire -40dBm to +3dBm (Note 22, Figure 9) -0.1 - 0.1 dB 4-Wire to 2-Wire -55dBm to -40dBm (Note 22, Figure 9) - ±0.03 - dB INSERTION LOSS GAIN TRACKING (Ref = -10dBm, at 1.0kHz) GRX = ((VTR1- VTR2)(300k))/(-3)(600) Where: VTR1 is the Tip to Ring Voltage with VRSN = 0V and VTR2 is the Tip to Ring Voltage with VRSN = -3V VRSN = 0V RRX TIP 5 RL 600Ω RSN 19 C VRSN = -3V RDC1 41.2kΩ VTR TIP 5 RL 600Ω 300kΩ VTX 21 RT 600kΩ IDCMET VTR EG RING 6 RDC 17 RDC2 CDC 41.2kΩ 1.5µF RRX 1/ωC << RL FIGURE 8. CURRENT GAIN-RSN TO METALLIC RING 6 RSN 19 VTX ERX 300kΩ FIGURE 9. FREQUENCY RESPONSE, INSERTION LOSS, GAIN TRACKING AND HARMONIC DISTORTION NOISE Idle Channel Noise at 2-Wire C-Message Weighting (Note 23, Figure 10) - 12 - dBrnC Idle Channel Noise at 4-Wire C-Message Weighting (Note 24, Figure 10) - 12 - dBrnC 2-Wire to 4-Wire 0dBm, 1kHz (Note 25, Figure 7) - -65 -54 dB 4-Wire to 2-Wire 0dBm, 0.3kHz to 3.4kHz (Note 26, Figure 9) - -65 -54 dB HARMONIC DISTORTION BATTERY FEED CHARACTERISTICS Constant Loop Current Tolerance RDCX = 41.2kΩ IL = 2500/(RDC1 + RDC2), -40oC to 85oC (Note 27) 0.9IL IL 1.1IL mA Loop Current Tolerance (Standby) IL = (VBAT-3)/(RL +1800), -40oC to 85oC (Note 28) 0.8IL IL 1.2IL mA Open Circuit Voltage (VTIP - VRING) -40oC to 85oC, (Active) 14 - 20 V LOOP CURRENT DETECTOR On-Hook to Off-Hook RD = 39kΩ, -40oC to 85oC 372/RD 465/RD 558/RD mA Off-Hook to On-Hook RD = 39kΩ, -40oC to 85oC 325/RD 405/RD 485/RD mA Loop Current Hysteresis RD = 39kΩ, -40oC to 85oC 25/RD 60/RD 95/RD mA GROUND KEY DETECTOR 5 HC5513 TA = -40oC to 85oC, VCC = 5V ±5%, VEE = -5V ±5%, VBAT = -28V, AGND = BGND = 0V, RDC1 = RDC2 = 41.2kΩ, RD = 39kΩ, RSG = ∞, RF1 = RF2 = 0Ω, CHP = 10nF, CDC = 1.5µF, ZL = 600Ω. (Continued) Electrical Specifications PARAMETER CONDITIONS MIN TYP MAX UNITS Tip/Ring Current Difference - Trigger (Note 29, Figure 11) 8 12 17 mA Tip/Ring Current Difference - Reset (Note 29, Figure 11) 3 7 12 mA Hysteresis (Note 29, Figure 11) 0 5 9 mA TIP 5 RL 600Ω TIP 5 VTX 21 RT 600kΩ VTR RSN 19 RDC1 41.2kΩ VTX CDC RDC2 RRX RING 6 RSN 19 RING RDC 6 DET 17 41.2kΩ 1.5µF 300kΩ E1 = C1 = 0, C2 = 1 FIGURE 10. IDLE CHANNEL NOISE FIGURE 11. GROUND KEY DETECT RING TRIP DETECTOR (DT, DR) Offset Voltage Source Res = 0 -20 - 20 mV Input Bias Current Source Res = 0 -500 - 500 nA Input Common-Mode Range Source Res = 0 VBAT +1 - 0 V Input Resistance Source Res = 0, Balanced 3 - - MΩ VSAT at 25mA IOL = 25mA - 1.0 1.5 V Off-State Leakage Current VOH = 12V - - 10 µA Input Low Voltage, VIL 0 - 0.8 V Input High Voltage, VIH 2 - VCC V RING RELAY DRIVER DIGITAL INPUTS (E0, E1, C1, C2) Input Low Current, IIL: C1, C2 VIL = 0.4V -200 - - µA Input Low Current, IIL: E0, E1 VIL = 0.4V -100 - - µA Input High Current VIH = 2.4V - - 40 µA Output Low Voltage, VOL IOL = 2mA - - 0.45 V Output High Voltage, VOH IOH = 100µA 2.7 - - V 10 15 20 kΩ DETECTOR OUTPUT (DET) Internal Pull-Up Resistor POWER DISSIPATION Open Circuit State C1 = C2 = 0 - - 23 mW On-Hook, Standby C1 = C2 = 1 - - 30 mW On-Hook, Active C1 = 0, C2 = 1, RL = High Impedance - - 150 mW Off-Hook, Active RL = 0Ω - - 1.1 W RL = 300Ω - - 0.75 W RL = 600Ω - - 0.5 W 150 - 180 oC TEMPERATURE GUARD Thermal Shutdown 6 HC5513 TA = -40oC to 85oC, VCC = 5V ±5%, VEE = -5V ±5%, VBAT = -28V, AGND = BGND = 0V, RDC1 = RDC2 = 41.2kΩ, RD = 39kΩ, RSG = ∞, RF1 = RF2 = 0Ω, CHP = 10nF, CDC = 1.5µF, ZL = 600Ω. (Continued) Electrical Specifications PARAMETER CONDITIONS MIN TYP MAX UNITS Open Circuit State (C1, 2 = 0, 0) - - 1.5 mA Standby State (C1, 2 = 1, 1) - - 1.7 mA Active State (C1, 2 = 0,1) - - 5.5 mA Open Circuit State (C1, 2 = 0, 0) - - 0.8 mA Standby State (C1, 2 = 1, 1) - - 0.8 mA Active State (C1, 2 = 0, 1) - - 2.2 mA Open Circuit State (C1, 2 = 0, 0) - - 0.4 mA Standby State (C1, 2 = 1, 1) - - 0.6 mA Active State (C1, 2 = 0, 1) - - 3.9 mA VCC to 2 or 4-Wire Port (Note 30, Figure 12) - 40 - dB VEE to 2 or 4-Wire Port (Note 30, Figure 12) - 40 - dB VBAT to 2 or 4-Wire Port (Note 30, Figure 12) - 40 - dB SUPPLY CURRENTS (VBAT = -28V) ICC, On-Hook IEE, On-Hook IBAT, On-Hook PSRR -48V SUPPLY 5V SUPPLY -5V SUPPLY 100mVRMS, 50Hz TO 4kHz TIP 5 VTX 21 PSRR = 20 log (VT X/VIN) RT 600kΩ RL 600Ω VTX RRX RING 6 RSN 19 300kΩ FIGURE 12. POWER SUPPLY REJECTION RATIO VTX IRSN + ITIP - LOOP CURRENT CIRCUIT TIP RRX RSN RDC1 ITIP IRING RING IRING + RDC2 RDC SATURATION GUARD CIRCUIT - -2.5V + A2 A1 HC5513 R1 - I2 I1 -5V + -5V RSG RSG -5V FIGURE 13. DC LOOP CURRENT 7 CDC HC5513 Circuit Operation and Design Information Constant Loop Current (DC) Path SLIC in the Active Mode The DC path establishes a constant loop current that flows out of tip and into the ring terminal. The loop current is programmed by resistors RDC1, RDC2 and the voltage on the RDC pin (Figure 13). The RDC voltage is determined by the voltage across R1 in the saturation guard circuit. Under constant current feed conditions, the voltage drop across R1 sets the RDC voltage to -2.5V. This occurs when current flows through R1 into the current source I2 . The RDC voltage establishes a current (IRSN) that is equal to VRDC/(RDC1 +RDC2). This current is then multiplied by 1000, in the loop current circuit, to become the tip and ring loop currents. For the purpose of the following discussion, the saturation guard voltage is defined as the maximum tip to ring voltage at which the SLIC can provide a constant current for a given battery and overhead voltage. For loop resistances that result in a tip to ring voltage less than the saturation guard voltage the loop current is defined as: 2.5V I L = -------------------------------------- × 1000 R DC1 + R DC2 (EQ. 1) where: IL = Constant loop current. TIP TO RING VOLTAGE (V) The following discussion separates the SLIC’s operation into its DC and AC path, then follows up with additional circuit and design information. VTIP SATURATION GUARD VOLTAGE -10 CONSTANT CURRENT FEED REGION RESISTIVE FEED REGION -20 -30 -40 SATURATION GUARD VOLTAGE -50 0 VRING ∞ 1.2K LOOP RESISTANCE (Ω) FIGURE 14. VTR vs RL Figure 15 shows the relationship between the saturation guard voltage, the loop current and the loop resistance. Notice from Figure 15 that for a loop resistance <1.2kΩ (RSG = 21.4kΩ) the SLIC is operating in the constant current feed region and for resistances >1.2kΩ the SLIC is operating in the resistive feed region. Operation in the resistive feed region allows long loop and off-hook transmission by keeping the tip and ring voltages off the rails. Operation in this region is transparent to the customer. 50 CONSTANT CURRENT FEED REGION VBAT = -48V, RSG = 21.4kΩ 40 SATURATION GUARD VOLTAGE, VTR = 38V 30 VBAT = -24V, RSG = ∞ 20 10 0 RDC1 and RDC2 = Loop current programming resistors. Capacitor CDC between RDC1 and RDC2 removes the VF signals from the battery feed control loop. The value of CDC is determined by Equation 2: VBAT = -48V, IL = 23mA, RSG = 21.4kΩ 0 TIP TO RING VOLTAGE (V) The HC5513 is a current feed voltage sense Subscriber Line Interface Circuit (SLIC). This means that for short loop applications the SLIC provides a programed constant current to the tip and ring terminals while sensing the tip to ring voltage. SATURATION GUARD VOLTAGE, VTR = 13V RESISTIVE FEED REGION 0 10 20 30 LOOP CURRENT (mA) RL 100kΩ 4kΩ 2kΩ <1.2kΩ RL 100kΩ 1.5kΩ 700Ω <400Ω RRSG = 21.4kΩ RRSG = ∞ Ω FIGURE 15. VTR vs IL AND RL 1 + --------------1 C DC = T × --------------R R DC1 (EQ. 2) DC2 where T = 30ms. NOTE: The minimum CDC value is obtained if RDC1 = RDC2. Figure 14 illustrates the relationship between the tip to ring voltage and the loop resistance. For a 0Ω loop resistance both tip and ring are at VBAT/2. As the loop resistance increases, so does the voltage differential between tip and ring. When this differential voltage becomes equal to the saturation guard voltage, the operation of the SLIC’s loop feed changes from a constant current feed to a resistive feed. The loop current in the resistive feed region is no longer constant but varies as a function of the loop resistance. 8 The Saturation Guard circuit (Figure 13) monitors the tip to ring voltage via the transconductance amplifier A1. A1 generates a current that is proportional to the tip to ring voltage difference. I1 is internally set to sink all of A1’s current until the tip to ring voltage exceeds 12.5V. When the tip to ring voltage exceeds 12.5V (with no RSG resistor) A1 supplies more current than I1 can sink. When this happens A2 amplifies its input current by a factor of 12 and the current through R1 becomes the difference between I2 and the output current from A2 . As the current from A2 increases, the voltage across R1 decreases and the output voltage on RDC decreases. This results in a corresponding decrease in the loop current. The RSG pin provides the ability to increase the saturation guard reference voltage beyond 12.5V. Equation 3 HC5513 gives the relationship between the RSG resistor value and the programmable saturation guard reference voltage: 5 5 • 10 V SGREF = 12.5 + -----------------R SG (EQ. 3) where: IL = Loop current in the standby state. RL = Loop resistance. where: VBAT = Battery voltage. VSGREF = Saturation Guard reference voltage. (AC) Transmission Path RSG = Saturation Guard programming resistor. SLIC in the Active Mode When the Saturation guard reference voltage is exceeded, the tip to ring voltage is calculated using Equation 4: 5 16.66 + 5 • 10 ⁄ R SG V TR = R L × ---------------------------------------------------------------------R + (R +R ) ⁄ 600 L DC1 (EQ. 4) Figure 16 shows a simplified AC transmission model. Circuit analysis yields the following design equations: V TR = V TX + I M • 2R F (EQ. 9) DC2 where: VTR = Voltage differential between tip and ring. RL = Loop resistance. For on-hook transmission RL = ∞, Equation 4 reduces to: 5 5 • 10 V TR = 16.66 + -----------------R SG (EQ. 5) The value of RSG should be calculated to allow maximum loop length operation. This requires that the saturation guard reference voltage be set as high as possible without clipping the incoming or outgoing VF signal. A voltage margin of -4V on tip and -4V on ring, for a total of -8V margin, is recommended as a general guideline. The value of RSG is calculated using Equation 6: 5 5 • 10 R SG = -------------------------------------------------------------------------------------------------------------------------------------------------( R DC1 + R DC2 ) ( V BAT – V MARGIN ) × 1 + ----------------------------------------- – 16.66V 600R L (EQ. 6) V TX V RX IM ---------- + ----------- = -----------Z T Z RX 1000 (EQ. 10) V TR = E G – I M • Z L (EQ. 11) where: VTR = Is the AC metallic voltage between tip and ring, including the voltage drop across the fuse resistors RF. VTX = Is the AC metallic voltage. Either at the ground referenced 4-wire side or the SLIC tip and ring terminals. IM = Is the AC metallic current. RF = Is a fuse resistor. ZT = Is used to set the SLIC’s 2-wire impedance. VRX = Is the analog ground referenced receive signal. ZRX = Is used to set the 4-wire to 2-wire gain. EG = Is the AC open circuit voltage. ZL = Is the line impedance. (AC) 2-Wire Impedance where: VBAT = Battery voltage. VMARGIN = Recommended value of -8V to allow a maximum overload level of 3.1VPEAK . For on-hook transmission, RL = ∞, Equation 6 reduces to: 5 5 • 10 R SG = ---------------------------------------------------------------------------V BAT – V MARGIN – 16.66V (EQ. 7) The AC 2-wire impedance (ZTR) is the impedance looking into the SLIC, including the fuse resistors, and is calculated as follows: Let VRX = 0. Then from Equation 10 IM V TX = Z T • ------------1000 (EQ. 12) ZTR is defined as: SLIC in the Standby Mode Overall system power is saved by configuring the SLIC in the standby state when not in use. In the standby state the tip and ring amplifiers are disabled and internal resistors are connected between tip to ground and ring to VBAT. This connection enables a loop current to flow when the phone goes off-hook. The loop current detector then detects this current and the SLIC is configured in the active mode for voice transmission. The loop current in standby state is calculated as follows: V BAT – 3V I L ≈ -------------------------------R L + 1800Ω (EQ. 8) 9 V TR TR = ---------IM (EQ. 13 Substituting in Equation 9 for VTR V TX 2R F • I M Z TR = ---------- + ----------------------IM IM (EQ. 14) HC5513 Substituting in Equation 12 for VTX ZT Z TR = ------------ + 2R F 1000 (EQ. 15) Z T ⁄ 1000 V TX A 2 – 4 = ---------- = ----------------------------------------V TR Z T ⁄ 1000 + 2R F Therefore (EQ. 16) Z T = 1000 • ( Z TR – 2R F ) Equation 16 can now be used to match the SLIC’s impedance to any known line impedance (ZTR). (EQ. 17 The 4-wire to 2-wire gain is equal to VTR/VRX . Example: From Equations 9, 10 and 11 with EG = 0: Calculate ZT to make ZTR = 600Ω in series with 2.16µF. RF = 20Ω: For applications where the 2-wire impedance (ZTR , ZL ZT V TR A 4 – 2 = ----------- • -------------------------------------------= – ---------ZT V RX Z RX ------------- + 2R F + Z L 1000 1 Z T = 1000 • 600 + ----------------------------------------- – 2 • 20 – 6 jω • 2.16 • 10 (EQ. 18) Equation 15) is chosen to equal the line impedance (ZL), the expression for A4-2 simplifies to: ZT 1 - • --A 4 – 2 = – ---------Z RX 2 (EQ. 19) ZT = 560kΩ in series with 2.16nF. (AC) 4-Wire to 4-Wire Gain (AC) 2-Wire to 4-Wire Gain The 4-wire to 4-wire gain is equal to VTX/VRX . The 2-wire to 4-wire gain is equal to VTX/ VTR . From Equations 9, 10 and 11 with EG = 0: From Equations 9 and 10 with VRX = 0: Z L + 2R F ZT V TX - • -------------------------------------------= – ---------A 4 – 4 = ----------ZT V RX Z RX ------------ + 2R F + Z L 1000 (AC) 4-Wire to 2-Wire Gain (EQ. 20) IM TIP A = 250 RF ZL VTR ZTR + VTX + - + VTX - 1 + VTX - + - ZT EG - IM A=4 RSN A = 250 RING RF IM 1000 ZRX + VRX - HC5513 FIGURE 16. SIMPLIFIED AC TRANSMISSION CIRCUIT Transhybrid Circuit The purpose of the transhybrid circuit is to remove the receive signal (VRX) from the transmit signal (VTX), thereby preventing an echo on the transmit side. This is accomplished by using an external op amp (usually part of the CODEC) and by the inversion of the signal from the 4-wire receive port (RSN) to the 4-wire transmit port (VTX). Figure 17 shows the transhybrid circuit. The input signal will 10 be subtracted from the output signal if I1 equals I2 . Node analysis yields the following equation: V TX V RX ---------- + ----------- = 0 R TX Z B (EQ. 21) HC5513 The value of ZB is then: V RX Z B = – R TX • ----------V (EQ. 22) TX Where VRX/VTX equals 1/ A4-4 . Therefore: ZT - + 2RF + Z L Z RX -----------1000 Z B = R TX • ----------- • -------------------------------------------ZT Z L + 2R F (EQ. 23) Given: RTX = 20kΩ, ZRX = 280kΩ, ZT = 562kΩ (standard value), RF = 20Ω and ZL= 600Ω, The value of ZB = 18.7kΩ. RFB I2 I TIP – I RING IL I RD = ----------------------------------- = --------600 300 RTX - + + VTX I1 - HC5513 ZT ZB (EQ. 24) The IRD current results in a voltage drop across RD that is compared to an internal 1.25V reference voltage. When the voltage drop across RD exceeds 1.25V, and the logic is configured for loop current detection, the DET pin goes low. + VRX The hysteresis resistor RH adds an additional voltage effectively across RD, causing the on-hook to off-hook threshold to be slightly higher than the off-hook to on-hook threshold. CODEC/ FILTER Taking into account the hysteresis voltage, the typical value of RD for the on-hook to off-hook condition is: - RSN ZRX FIGURE 17. TRANSHYBRID CIRCUIT Supervisory Functions The loop current, ground key and the ring trip detector outputs are multiplexed to a single logic output pin called DET. See Table 1 to determine the active detector for a given logic input. For further discussion of the logic circuitry see section titled “Digital Logic Inputs”. Before proceeding with an explanation of the loop current detector, ground key detector and later the longitudinal impedance, it is important to understand the difference between a “metallic” and “longitudinal” loop currents. Figure 18 illustrates 3 different types of loop current encountered. Case 1 illustrates the metallic loop current. The definition of a metallic loop current is when equal currents flow out of tip and into ring. Loop current is a metallic current. Cases 2 and 3 illustrate the longitudinal loop current. The definition of a longitudinal loop current is a common mode current, that flows either out of or into tip and ring simultaneously. Longitudinal currents in the on-hook state result in equal currents flowing through the sense resistors R1 and R2 (Figure 18). And longitudinal currents in the off11 Loop Current Detector Figure 18 shows a simplified schematic of the loop current and ground key detectors. The loop current detector works by sensing the metallic current flowing through resistors R1 and R2 . This results in a current (IRD) out of the transconductance amplifier (gm1) that is equal to the product of gm1 and the metallic loop current. IRD then flows out the RD pin and through resistor RD to VEE . The value of IRD is equal to: Example: VTX hook state result in unequal currents flowing through the sense resistors R1 and R2 . Notice that for case 2, longitudinal currents flowing away from the SLIC, the current through R1 is the metallic loop current plus the longitudinal current; whereas the current through R2 is the metallic loop current minus the longitudinal current. Longitudinal currents are generated when the phone line is influenced by magnetic fields (e.g., power lines). 465 R D = ------------------------------------------------------------------------I ON – HOOK to OFF – HOOK (EQ. 25) Taking into account the hysteresis voltage, the typical value of RD for the off-hook to on-hook condition is: 375 R D = -------------------------------------------------------------------------I OFF – HOOK to ON – HOOK (EQ. 26) HC5513 gm1(IMETALLIC) RD RH + TIP R1 gm1 CD - VREF 1.25V VEE -5V IGK - CASE 3 + IMETALLIC ILONGITUDINAL ILONGITUDINAL ¨ ¨ Æ IMETALLIC ILONGITUDINAL ILONGITUDINAL Æ ¨ Æ - gm2(ITIP - IRING) RING CASE 2 RD + gm2 R2 CASE 1 IRD CURRENT LOOP COMPARATOR + - RH + - GROUND KEY COMPARATOR HC5513 D2 I1 D1 DIGITAL MULTIPLEXER DET FIGURE 18. LOOP CURRENT AND GROUND KEY DETECTORS A filter capacitor (CD) in parallel with RD will improve the accuracy of the trip point in a noisy environment. The value of this capacitor is calculated using the following Equation: off-hook, the SLIC is commanded by the logic inputs to go into the active state. In the active state, tip and ring are once again connected to the phone and normal operation ensues. T C D = -------RD Figure 19 illustrates battery backed unbalanced ring injected ringing. For tip injected ringing just reverse the leads to the phone. The ringing source could also be balanced. (EQ. 27) Where: T = 0.5ms. Ground Key Detector A simplified schematic of the ground key detector is shown in Figure 18. Ground key, is the process in which the ring terminal is shorted to ground for the purpose of signaling an Operator or seizing a phone line (between the Central Office and a Private Branch Exchange). The Ground Key detector is activated when unequal current flow through resistors R1 and R2. This results in a current (IGK) out of the transconductance amplifier (gm2) that is equal to the product of gm2 and the differential (ITIP IRING) loop current. If IGK is less than the internal current source (I1), then diode D1 is on and the output of the ground key comparator is low. If IGK is greater than the internal current source (I1), then diode D2 is on and the output of the ground key comparator is high. With the output of the ground key comparator high, and the logic configured for ground key detect, the DET pin goes low. The ground key detector has a built in hysteresis of typically 5mA between its trigger and reset values. Ring Trip Detector NOTE: The DET output will toggle at 20Hz because the DT input is not completely filtered by CRT. Software can examine the duty cycle and determine if the DET pin is low for more that half the time, if so the off-hook condition is indicated. CRT R3 RRT R1 DT - + DET DR TIP R4 ERG R2 RING TRIP COMPARATOR VBAT RING RINGRLY RING RELAY HC5513 FIGURE 19. RING TRIP CIRCUIT FOR BATTERY BACKED RINGING Longitudinal Impedance Ring trip detection is accomplished with the internal ring trip comparator and the external circuitry shown in Figure 19. The process of ring trip is initiated when the logic input pins are in the following states: E0 = 0, E1 = 1/0, C1 = 1 and C2 = 0. This logic condition connects the ring trip comparator to the DET output, and causes the Ringrly pin to energize the ring relay. The ring relay connects the tip and ring of the phone to the external circuitry in Figure 19. When the phone is on-hook the DT pin is more positive than the DR pin and the DET output is high. For off-hook conditions DR is more positive than DT and DET goes low. When DET goes low, indicating that the phone has gone 12 The feedback loop described in Figure 20(A, B) realizes the desired longitudinal impedances from tip to ground and from ring to ground. Nominal longitudinal impedance is resistive and in the order of 22Ω. In the presence of longitudinal currents this circuit attenuates the voltages that would otherwise appear at the tip and ring terminals, to levels well within the common mode range of the SLIC. In fact, longitudinal currents may exceed the programmed DC loop current without disturbing the SLIC’s VF transmission capabilities. HC5513 The function of this circuit is to maintain the tip and ring voltages symmetrically around VBAT/2, in the presence of longitudinal currents. The differential transconductance amplifiers GT and GR accomplish this by sourcing or sinking the required current to maintain VC at VBAT/2. When a longitudinal current is injected onto the tip and ring inputs, the voltage at VC moves from it’s equilibrium value VBAT/2. When VC changes by the amount ∆VC , this change appears between the input terminals of the differential transconductance amplifiers GT and GR . The output of GT and GR are the differential currents ∆I1 and ∆I2 , which in turn feed the differential inputs of current sources IT and IR respectively. IT and IR have current gains of 250 single ended and 500 differentially, thus leading to a change in IT and IR that is equal to 500(∆I) and 500(∆I2). The circuit shown in Figure 20(B) illustrates the tip side of the longitudinal network. The advantages of a differential input current source are: improved noise since the noise due to current source 2IO is now correlated, power savings due to differential current gain and minimized offset error at the Operational Amplifier inputs via the two 5kΩ resistors. Digital Logic Inputs Open Circuit State (C1 = 0, C2 = 0) In this state the SLIC is effectively off. All detectors and both the tip and ring line drive amplifiers are powered down, presenting a high impedance to the line. Power dissipation is at a minimum. Active State (C1 = 0, C2 = 1) The tip output is capable of sourcing loop current and for open circuit conditions is about -4V from ground. The ring output is capable of sinking loop current and for open circuit conditions is about VBAT + 4V. VF signal transmission is normal. The loop current and ground key detectors are both active, E0 and E1 determine which detector is gated to the DET output. Ringing State (C1 = 1, C2 = 0) The ring relay driver and the ring trip detector are activated. Both the tip and ring line drive amplifiers are powered down. Both tip and ring are disconnected from the line via the external ring relay. Standby State (C1 = 1, C2 = 1) Table 1 is the logic truth table for the TTL compatible logic input pins. The HC5513 has two enable inputs pins (E0, E1) and two control inputs pins (C1, C2). The enable pin E0 is used to enable or disable the DET output pin. The DET pin is enabled if E0 is at a logic level 0 and disabled if E0 is at a logic level 1. The enable pin E1 gates the ground key detector to the DET output with a logic level 0, and gates the loop or ring trip detector to the DET output with a logic level 1. ILONG A combination of the control pins C1 and C2 is used to select 1 of the 4 possible operating states. A description of each operating state and the control logic follow: ILONG Both the tip and ring line drive amplifiers are powered down. Internal resistors are connected between tip to ground and ring to VBAT to allow loop current detect in an off-hook condition. The loop current and ground key detectors are both active, E0 and E1 determine which detector is gated to the DET output. AC Transmission Circuit Stability To ensure stability of the AC transmission feedback loop two compensation capacitors CTC and CRC are required. Figure 21 (Application Circuit) illustrates their use. Recommended value is 2200pF. IT TIP ∆I1 ∆I1 + ∆VT TIP CURRENT SOURCE WITH DIFFERENTIAL INPUTS 20Ω TIP - GT RLARGE 5kΩ 5kΩ - + RLARGE VC VBAT/2 + GR VC ∆I2 + ∆VR - RING HC5513 ∆I2 2I0 RLARGE IR RING FIGURE 20A. FIGURE 20. LONGITUDINAL IMPEDANCE NETWORK 13 VBAT/2 RLARGE ILONG ILONG ∆I1 ∆I1 - TIP DIFFERENTIAL TRANSCONDUCTANCE AMPLIFIER FIGURE 20B. GT HC5513 AC-DC Separation Capacitor, CHP The high pass filter capacitor connected between pins HPT and HPR provides the separation between circuits sensing tip to ring DC conditions and circuits processing AC signals. A 10nf CHP will position the low end frequency response 3dB break point at 48Hz. Where: 1 (EQ. 28 3dB = ---------------------------------------------------( 2 • π • R HP • C HP ) Positive transients on tip or ring are clamped to within a couple of volts above ground via diodes D1 and D2 . Under normal operating conditions D1 and D2 are reverse biased and out of the circuit. Negative transients on tip and ring are clamped to within a couple of volts below ground via diodes D3 and D4 with the help of a Surgector. The Surgector is required to block conduction through diodes D3 and D4 under normal operating conditions and allows negative surges to be returned to system ground. The fuse resistors (RF) serve a dual purpose of being nondestructive power dissipaters during surge and fuses when the line in exposed to a power cross. Where RHP = 330kΩ. Power-Up Sequence Thermal Shutdown Protection The HC5513 has no required power-up sequence. This is a result of the Dielectrically Isolated (DI) process used in the fabrication of the part. By using the DI process, care is no longer required to insure that the substrate be kept at the most negative potential as with junction isolated ICs. The HC5513’s thermal shutdown protection is invoked if a fault condition on the tip or ring causes the temperature of the die to exceed 160oC. If this happens, the SLIC goes into a high impedance state and will remain there until the temperature of the die cools down by about 20oC. The SLIC will return back to its normal operating mode, providing the fault condition has been removed. Surge Voltage Protection The HC5513 must be protected against surge voltages and power crosses. Refer to “Maximum Ratings” TIPX and RINGX terminals for maximum allowable transient tip and ring voltages. The protection circuit shown in Figure 21 utilizes diodes together with a clamping device to protect tip and ring against high voltage transients. Printed Circuit Board Layout Care in the printed circuit board layout is essential for proper operation. All connections to the RSN pin should be made as close to the device pin as possible, to limit the interference that might be injected into the RSN terminal. It is good practice to surround the RSN pin with a ground plane. The analog and digital grounds should be tied together at the device. SLIC Operating States TABLE 1. LOGIC TRUTH TABLE E0 E1 C1 C2 0 0 0 0 Open Circuit SLIC OPERATING STATE 0 0 0 1 0 0 1 0 0 0 1 0 1 0 0 0 ACTIVE DETECTOR DET OUTPUT No Active Detector Logic Level High Active Ground Key Detector Ground Key Status Ringing No Active Detector Logic Level High 1 Standby Ground Key Detector Ground Key Status 0 0 Open Circuit No Active Detector Logic Level High 1 0 1 Active Loop Current Detector Loop Current Status 1 1 0 Ringing Ring Trip Detector Ring Trip Status 1 1 1 Standby Loop Current Detector Loop Current Status 14 HC5513 TABLE 1. LOGIC TRUTH TABLE E0 E1 C1 C2 1 0 0 0 Open Circuit SLIC OPERATING STATE No Active Detector ACTIVE DETECTOR 1 0 0 1 Active Ground Key Detector 1 0 1 0 Ringing No Active Detector 1 0 1 1 Standby Ground Key Detector 1 1 0 0 Open Circuit No Active Detector 1 1 0 1 Active Loop Current Detector 1 1 1 0 Ringing Ring Trip Detector 1 1 1 1 Standby Loop Current Detector DET OUTPUT Logic Level High Notes Where: ZD = The desired impedance; e.g., the characteristic impedance of the line, nominally 600Ω. (Reference Figure 6). 2. Overload Level (Two-Wire port) - The overload level is specified at the 2-wire port (VTR0) with the signal source at the 4-wire receive port (ERX). IDCMET = 30µA, increase the amplitude of ERX until 1% THD is measured at VTRO . Reference Figure 1. 3. Longitudinal Impedance - The longitudinal impedance is computed using the following equations, where TIP and RING voltages are referenced to ground. LZT, LZR , VT, VR , AR and AT are defined in Figure 2. (TIP) LZT = VT /AT (RING) LZR = VR /AR Where: EL = 1VRMS (0Hz to 100Hz). 4. Longitudinal Current Limit (Off-Hook Active) - Off-Hook (Active, C1 = 1, C2 = 0) longitudinal current limit is determined by increasing the amplitude of EL (Figure 3A) until the 2-wire longitudinal balance drops below 45dB. DET pin remains low (no false detection). 5. Longitudinal Current Limit (On-Hook Standby) - On-Hook (Active, C1 = 1, C2 = 1) longitudinal current limit is determined by increasing the amplitude of EL (Figure 3B) until the 2-wire longitudinal balance drops below 45dB. DET pin remains high (no false detection). 6. Longitudinal to Metallic Balance - The longitudinal to metallic balance is computed using the following equation: BLME = 20 • log (EL /VTR), where: EL and VTR are defined in Figure 4. 7. Metallic to Longitudinal FCC Part 68, Para 68.310 - The metallic to longitudinal balance is defined in this spec. 8. Longitudinal to Four-Wire Balance - The longitudinal to 4-wire balance is computed using the following equation: BLFE = 20 • log (EL /VTX),: EL and VTX are defined in Figure 4. 9. Metallic to Longitudinal Balance - The metallic to longitudinal balance is computed using the following equation: BMLE = 20 • log (ETR /VL), ERX = 0 Where: ETR , VL and ERX are defined in Figure 5. 10. Four-Wire to Longitudinal Balance - The 4-wire to longitudinal balance is computed using the following equation: BFLE = 20 • log (ERX /VL), ETR = source is removed. Where: ERX , VL and ETR are defined in Figure 5. 11. Two-Wire Return Loss - The 2-wire return loss is computed using the following equation: r = -20 • log (2VM /VS) 15 12. Overload Level (4-Wire port) - The overload level is specified at the 4-wire transmit port (VTXO) with the signal source (EG) at the 2-wire port, IDCMET = 23mA, ZL = 20kΩ (Reference Figure 7). Increase the amplitude of EG until 1% THD is measured at VTXO . Note that the gain from the 2-wire port to the 4-wire port is equal to 1. 13. Output Offset Voltage - The output offset voltage is specified with the following conditions: EG = 0, IDCMET = 23mA, ZL = ∞ and is measured at VTX . EG , IDCMET, VTX and ZL are defined in Figure 7. Note: IDCMET is established with a series 600Ω resistor between tip and ring. HC5513 14. Two-Wire to Four-Wire (Metallic to VTX) Voltage Gain - The 2-wire to 4-wire (metallic to VTX) voltage gain is computed using the following equation. G2-4 = (VTX /VTR), EG = 0dBm0, VTX , VTR , and EG are defined in Figure 7. 15. Current Gain RSN to Metallic - The current gain RSN to Metallic is computed using the following equation: K = IM [(RDC1 + RDC2)/(VRDC - VRSN)] K, IM , RDC1 , RDC2 , VRDC and VRSN are defined in Figure 8. 16. Two-Wire to Four-Wire Frequency Response - The 2-wire to 4-wire frequency response is measured with respect to EG = 0dBm at 1.0kHz, ERX = 0V, IDCMET = 23mA. The frequency response is computed using the following equation: F2-4 = 20 • log (VTX /VTR), vary frequency from 300Hz to 3.4kHz and compare to 1kHz reading. VTX , VTR , and EG are defined in Figure 9. 17. Four-Wire to Two-Wire Frequency Response - The 4-wire to 2-wire frequency response is measured with respect to ERX = 0dBm at 1.0kHz, EG = 0V, IDCMET = 23mA. The frequency response is computed using the following equation: F4-2 = 20 • log (VTR /ERX), vary frequency from 300Hz to 3.4kHz and compare to 1kHz reading. VTR and ERX are defined in Figure 9. 18. Four-Wire to Four-Wire Frequency Response - The 4-wire to 4-wire frequency response is measured with respect to ERX = 0dBm at 1.0kHz, EG = 0V, IDCMET = 23mA. The frequency response is computed using the following equation: F4-4 = 20 • log (VTX /ERX), vary frequency from 300Hz to 3.4kHz and compare to 1kHz reading. VTX and ERX are defined in Figure 9. 19. Two-Wire to Four-Wire Insertion Loss - The 2-wire to 4-wire insertion loss is measured with respect to EG = 0dBm at 1.0kHz input signal, ERX = 0, IDCMET = 23mA and is computed using the following equation: L2-4 = 20 • log (VTX /VTR) where: VTX , VTR , and EG are defined in Figure 9. (Note: The fuse resistors, RF, impact the insertion loss. The specified insertion loss is for RF = 0). 20. Four-Wire to Two-Wire Insertion Loss - The 4-wire to 2-wire insertion loss is measured based upon ERX = 0dBm, 1.0kHz input signal, EG = 0, IDCMET = 23mA and is computed using the following equation: L4-2 = 20 • log (VTR /ERX) Where: VTR and ERX are defined in Figure 9. 21. Two-Wire to Four-Wire Gain Tracking - The 2-wire to 4-wire gain tracking is referenced to measurements taken for EG = -10dBm, 1.0kHz signal, ERX = 0, IDCMET = 23mA and is computed using the following equation. G2-4 = 20 • log (VTX /VTR) vary amplitude -40dBm to +3dBm, or -55dBm to -40dBm and compare to -10dBm reading. VTX and VTR are defined in Figure 9. 22. Four-Wire to Two-Wire Gain Tracking - The 4-wire to 2-wire gain tracking is referenced to measurements taken for ERX = -10dBm, 1.0kHz signal, EG = 0, IDCMET = 23mA and is computed using the following equation: G4-2 = 20 • log (VTR /ERX) vary amplitude -40dBm to +3dBm, or -55dBm to -40dBm and compare to -10dBm reading. VTR and ERX are defined in Figure 9. The level is specified at the 4-wire receive port and referenced to a 600Ω impedance level. 23. Two-Wire Idle Channel Noise - The 2-wire idle channel noise at VTR is specified with the 2-wire port terminated in 600Ω (RL) and with the 4-wire receive port grounded (Reference Figure 10). 24. Four-Wire Idle Channel Noise - The 4-wire idle channel noise at VTX is specified with the 2-wire port terminated in 600Ω (RL). The noise specification is with respect to a 600Ω impedance level at VTX. The 4-wire receive port is grounded (Reference Figure 10). 25. Harmonic Distortion (2-Wire to 4-Wire) - The harmonic distortion is measured with the following conditions. EG = 0dBm at 1kHz, IDCMET = 23mA. Measurement taken at VTX. (Reference Figure 7). 26. Harmonic Distortion (4-Wire to 2-Wire) - The harmonic distortion is measured with the following conditions. ERX = 0dBm0. Vary frequency between 300Hz and 3.4kHz, IDCMET = 23mA. Measurement taken at VTR. (Reference Figure 9). 27. Constant Loop Current - The constant loop current is calculated using the following equation: IL = 2500 / (RDC1 + RDC2) 28. Standby State Loop Current - The standby state loop current is calculated using the following equation: IL = [|VBAT| - 3] / [RL +1800], TA = 25oC 29. Ground Key Detector - (TRIGGER) Increase the input current to 8mA and verify that DET goes low. (RESET) Decrease the input current from 17mA to 3mA and verify that DET goes high. (Hysteresis) Compare difference between trigger and reset. 30. Power Supply Rejection Ratio - Inject a 100mVRMS signal (50Hz to 4kHz) on VBAT, VCC and VEE supplies. PSRR is computed using the following equation: PSRR = 20 • log (VTX /VIN). VTX and VIN are defined in Figure 12. Pin Descriptions PDIP SYMBOL DESCRIPTION 7 BGND Battery Ground - To be connected to zero potential. All loop current and longitudinal current flow from this ground. Internally separate from AGND but it is recommended that it is connected to the same potential as AGND. 8 VCC 9 RINGRLY 10 VBAT Battery supply voltage, -24V to -56V. 11 RSG Saturation guard programming resistor pin. 5V power supply. Ring relay driver output. 16 HC5513 Pin Descriptions (Continued) PDIP SYMBOL DESCRIPTION 12 E1 TTL compatible logic input. The logic state of E1 in conjunction with the logic state of C1 determines which detector is gated to the DET output. 13 E0 TTL compatible logic input. Enables the DET output when set to logic level zero and disables DET output when set to a logic level one. 14 DET Detector output. TTL compatible logic output. A zero logic level indicates that the selected detector was triggered (see Truth Table for selection of Ground Key detector, Loop Current detector or the Ring Trip detector). The DET output is an open collector with an internal pull-up of approximately 15kΩ to VCC. 15 C2 TTL compatible logic input. The logic states of C1 and C2 determine the operating states (Open Circuit, Active, Ringing or Standby) of the SLIC. 16 C1 TTL compatible logic input. The logic states of C1 and C2 determine the operating states (Open Circuit, Active, Ringing or Standby) of the SLIC. 17 RDC 18 AGND 19 RSN Receive Summing Node. The AC and DC current flowing into this pin establishes the metallic loop current that flows between tip and ring. The magnitude of the metallic loop current is 1000 times greater than the current into the RSN pin. The constant current programming resistors and the networks for program receive gain and 2-wire impedance all connect to this pin. 20 VEE -5V power supply. 21 VTX Transmit audio output. This output is equivalent to the TIP to RING metallic voltage. The network for programming the 2-wire input impedance connects between this pin and RSN. 22 HPR RING side of AC/DC separation capacitor CHP . CHP is required to properly separate the ring AC current from the DC loop current. The other end of CHP is connected to HPT. 1 HPT TIP side of AC/DC separation capacitor CHP . CHP is required to properly separate the tip AC current from the DC loop current. The other end of CHP is connected to HPR. 2 RD Loop current programming resistor. Resistor RD sets the trigger level for the loop current detect circuit. A filter capacitor CD is also connected between this pin and VEE. 3 DT Input to ring trip comparator. Ring trip detection is accomplished by connecting an external network to a comparator in the SLIC with inputs DT and DR. 4 DR Input to ring trip comparator. Ring trip detection is accomplished by connecting an external network to a comparator in the SLIC with inputs DT and DR. TIPSENSE 5 TIPX 6 RINGX N/C DC feed current programming resistor pin. Constant current feed is programmed by resistors RDC1 and RDC2 connected in series from this pin to the receive summing node (RSN). The resistor junction point is decoupled to AGND to isolate the AC signal components. Analog ground. Internally connected to output of tip power amplifier. Output of tip power amplifier. Output of ring power amplifier. No internal connection. 17 HC5513 Pinout HC5513 (PDIP) TOP VIEW HPT 1 22 HPR RD 2 21 VTX DT 3 20 VEE DR 4 19 RSN TIPX 5 18 AGND RINGX 6 17 RDC BGND 7 16 C1 VCC 8 15 C2 RINGRLY 18 9 14 DET VBAT 10 13 E0 RSG 11 12 E1 HC5513 Application Circuit RRT CRT CHP (NOTE 32) R1 RFB R3 RD U1 1 HPT -5V R2 R4 PTC RF1 3 DT VEE 20 4 DR RSN 19 D1 D3 PTC 7 BGND RF2 RT RB RRX RDC1 RDC 17 RDC2 CRC D4 - CODEC/FILTER CTC NOTE 31 RING 8 VCC C1 16 6 RINGX C2 15 10 VBAT DET 14 CDC D2 Surgector K VBAT A G D5 RINGING (VBAT + 90VRMS) +5V OR 12V 9 RINGRLY EO 13 11 RSG E1 12 RSG RELAY -5V D6 U1 SLIC (Subscriber Line Interface Circuit) HC5513 U2 Combination CODEC/Filter e.g. CD22354A or Programmable CODEC/ Filter, e.g. SLAC CDC 1.5µF, 20%, 10V RF1, RF2 Line Resistor, 20Ω, 1% Match, 2 W Carbon column resistor or thick film on ceramic R1, R3 200kΩ, 5%, 1/4W R2 910kΩ, 5%, 1/4W R4 1.2MΩ, 5%, 1/4W CHP 10nF, 20%, 100V (Note 2) RB 18.7kΩ,1%, 1/4W CRT 0.39µF, 20%, 100V RD 39kΩ, 5%, 1/4W CTC, CRC 2200pF, 20%, 100V RDC1, RDC2 41.2kΩ, 5%, 1/4W Relay Relay, 2C Contacts, 5V or 12V Coil D1 - D5 IN4007 Diode RT 562kΩ, 1%, 1/4W PTC Polyswitch TR600-150 D6 Diode, 1N4454 RFB 20.0kΩ, 1%, 1/4W RRX 280kΩ, 1%, 1/4W Surgector SGT27S10 RTX 20kΩ, 1%, 1/4W RRT 150Ω, 5%, 2W RSG VBAT = -28V, RSG = ∞ VBAT = -48V, RSG = 21.4kΩ, 1/4W 5% NOTES: 31. It is recommended that the anodes of D3 and D4 be shorted to ground through a battery referenced surgector (SGT27S10). 32. To meet the specified 25dB 2-wire return loss at 200Hz, CHP needs to be 20nF, 20%, 100V. FIGURE 21. APPLICATION CIRCUIT 19 U2 + -5V AGND 18 5 TIPX TIP RTX VTX 21 2 RD VBAT HPR 22 HC5513 Dual-In-Line Plastic Packages (PDIP) N E22.4 (JEDEC MS-010-AA ISSUE C) E1 INDEX AREA 1 2 3 22 LEAD DUAL-IN-LINE PLASTIC PACKAGE N/2 INCHES -B- SYMBOL -AD E BASE PLANE -C- A2 SEATING PLANE A L D1 e B1 D1 eA A1 eC B 0.010 (0.25) M C L C A B S C eB NOTES: 1. Controlling Dimensions: INCH. In case of conflict between English and Metric dimensions, the inch dimensions control. MILLIMETERS MIN MAX MIN MAX NOTES A - 0.210 - 5.33 4 A1 0.015 - 0.39 - 4 A2 0.125 0.195 3.18 4.95 - B 0.014 0.022 0.356 0.558 - B1 0.045 0.065 1.15 1.65 8 C 0.009 0.015 0.229 0.381 - D 1.065 1.120 27.06 D1 0.005 - 0.13 28.44 - 5 5 E 0.390 0.425 9.91 10.79 6 E1 0.330 0.390 8.39 9.90 5 e 0.100 BSC 2.54 BSC - 2. Dimensioning and tolerancing per ANSI Y14.5M-1982. eA 0.400 BSC 10.16 BSC 6 3. Symbols are defined in the “MO Series Symbol List” in Section 2.2 of Publication No. 95. eB - 0.500 - 12.70 7 4. Dimensions A, A1 and L are measured with the package seated in JEDEC seating plane gauge GS-3. L 0.115 0.160 2.93 4.06 4 N 22 22 5. D, D1, and E1 dimensions do not include mold flash or protrusions. Mold flash or protrusions shall not exceed 0.010 inch (0.25mm). 6. E and eA are measured with the leads constrained to be perpendicular to datum -C- . 9 Rev. 0 12/93 7. eB and eC are measured at the lead tips with the leads unconstrained. eC must be zero or greater. 8. B1 maximum dimensions do not include dambar protrusions. Dambar protrusions shall not exceed 0.010 inch (0.25mm). 9. N is the maximum number of terminal positions. 10. Corner leads (1, N, N/2 and N/2 + 1) for E8.3, E16.3, E18.3, E28.3, E42.6 will have a B1 dimension of 0.030 - 0.045 inch (0.76 - 1.14mm). All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9000 quality systems. Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries. For information regarding Intersil Corporation and its products, see www.intersil.com 20