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| (R) MH88631 Central Office Interface (LS/GS) Preliminary Information Features * * * * * * * * * * * * Transformerless 2-4 wire conversion Line state detection outputs - forward current - reverse current - ring ground - tip ground - ringing voltage Programmable audio transmit and receive gain Loop start or ground start termination Selectable 600 or AT&T compromise balance network -1 version: 20Hz Ringing Voltage -2 version: 50Hz Ringing Voltage ISSUE 4 April 1995 Ordering Information MH88631-1 MH88631-2 40 Pin SIL Package 40 Pin SIL Package 0C to 70C Description The Mitel MH88631-1, 2 Central Office Trunk Interface circuit provides a complete audio and signalling link between audio switching equipment and a central office. The loop seize circuitry is controlled by an external input to provide either a loop start of ground start termination. The device is fabricated using thick film ceramic technology to achieve high density circuit design. Applications * * * * PBX Channel bank Intercom Key System RG FC RV RC TG LPGND RINGND VCC+ VCC- AGND T R Signal Detection Circuitry Ring Ground Relay Driver 1 Relay Driver 2 RC1 RD1 RGND CD RD2 RC2 NETBAL Network Balance VTR+ VTRRXINRXIN+ Active Termination Audio Section Circuitry (2-4 Wire) GSX VX VR GSR QB QE XA XB XC VDD VEE RXOUT TXIN+ TXIN- Figure 1 - Functional Block Diagram 2-225 MH88631 LPGND VDD RINGND T R VTRVTR+ XC XA QE AGND RXIN+ RXINVEE TG RC RV FC RG QB Preliminary Information 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 XB VEE VDD RXOUT VCC+ GSR TXINVCCTXIN+ AGND VR VX RGND GSX RC1 NETBAL RD1 CD RD2 RC2 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 Figure 2 - Pin Connections Pin Description Pin # 1 2 3 Name LPGND VDD RINGND Description Loop Ground is the system ground reference with respect to -48V. Positive Power Supply (+5V). Ring Ground (Input). For Ground Start Trunk only a logic low input will enable the trunk circuit to ground the Ring lead through a low resistance (390). This is a signal to the C.O. that the interface is seizing the line. Tip (Input). Normally connects to the "Tip" lead of the C.O. Ring (Input). Normally connects to the "Ring" lead of the C.O. Connects to the TXIN+ (Pin 29) via an external capacitor (C1). Connects to the collector of an external transistor (Q1) and TXIN- (Pin 27) via an external capacitor (C4) External relay contact (K1) connection from XB (Pin 21), activates by loop seize control input (RC1). External relay contact (K1) connection from VTR+ (Pin 7), activated by loop seize control input (RC1). Connects to the emitter of an external transistor (Q1). Analog Ground. Differential Receive (Input). Connects to analog ground via an external capacitor (C2). Differential Receive (Input). Connects to RXOUT (Pin 24) via an external capacitor (C3). Negative Power Supply. (-5V). Tip Lead Ground Detect (Output). Active low. Reverse Loop Current Detect (Output). Active low. Ringing Voltage Detect (Output). Active low. Forward Loop Current Detect (Output). Active low Ring Lead detect (Output). Active low. Connects to the base of an external transistor (Q1). 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 2-226 T R VTRVTR+ XC XA QE AGND RXIN+ RXINVEE TG RC RV FC RG QB Preliminary Information Pin Description (Continued) Pin # 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 MH88631 Description Name XB VEE VDD RXOUT VCC+ GSR TXINVCCTXIN+ AGND VR VX RGND GSX RC1 NETBAL RD1 CD RD2 RC2 External relay contact (K1) connection from XC (Pin 8), activated by loop seize control input (RC1). Negative Power Supply. (-5V). Positive Power Supply. (+5V) Audio receive signal (output) tothe RXIN- (Pin 13), via an external decoupling capacitor (C3). Positive analog Power Supply Voltage. (+12V). Gain Setting Receive (Input). Normally used to set the receive gain with an external resistor connected to RXOUT (Pin 24). Transmit (Input). Differential audio signal from VTR- (Pin 6), via an external capacitor (C4). Negative Analog Power Supply Voltage. (-12V). Transmit (Input). Differential audio signal from VTR- (Pin 6), via an external decoupling capacitor (C1). Analog Ground. Audio Receive (Input). The four-wire audio signal input to the interface. Audio Transmit (Output). The four-wire audio signal output from the interface. Relay Ground. Gain Setting Transmit (Input). Normally used to set the transmit gain with an external resistor connected to VX (Pin 32). Relay Control 1 (Input). A logic high will activate the relay (K1) to provide loop seize across Tip and Ring. Network Balance (Input). When there is no connection (open), the network is balanced at 600. When the pin is grounded, the network is balanced at AT&T compromise. Relay Driver 1 (Output). Open collector sinks current when RC1 is high. Diode clamp protected. Clamping Diode. Normally connects to the positive supply voltage. Relay Driver 2 (Output). Open collector sinks current when RC2 is high. Diode clamp protected. Relay Driver 2 (Input). A logic high will activate the relay (K2) to provide proper biasing to the Tip and Ring. This input control is used for Ground Start Trunk only. 39 40 2-227 MH88631 Functional Description The MH88631-1, 2, is a Central Office Loop Start and/or Ground start analog Trunk interface circuit providing a complete audio and signalling link to the Central Office. The trunk interface circuit performs transformerless 2 to 4 wire conversion, between the 2-wire telephone loop and the 4 wire transmit and receive pairs of a voice switching system. The 4-wire connection can be interfaced to a filter/ codec, such as the MT896X, for use in a digital voice switched system. Voiceband analog signals, coming for the C.O., applied differentially across Tip and Ring, pass through a bridge rectifier and appear at VTR+ and VTR- where they are actively terminated. Refer to Fig. 3 - Application Circuit. External capacitors C1 and C4 couple the incoming signals into the balanced input of the Transmit audio circuitry via TXIN+ and TXIN-. The transmit gain is adjusted by feedback resistor R4. For best performance R4 should be physically located as close as possible to the GSX pin. The gain adjusted transmit signal appears at the Vx output pin. Relay K1 is the loop seize which applies active line termination and also provides biasing of the current modulator circuitry. Activating and deactivating K1 provides dial pulsing. Q1 is the current modulator output transistor, referred to as the loop driver transistor. Outgoing analog signals from the system are provided to the interface at the VR input where they enter an amplifier section with the gain controlled by the selection of the Rx gain feedback resistor R3. For best performance, R3 should be physically located as close as possible to the GSR pin. The output of the amplifier, RXOUT, is coupled to RXIN-, the current modulator circuitry, via C3. The balanced input to the current modulator is completed with the connection of C2 from RXIN+ to ground. Transmission to the C.O. is accomplished by modulating the loop with the outgoing analog signals. To ensure that the transmitted signals are not coupled to the receive circuitry, transhybrid loss is maximised. The impedance matching, performed by the balance network reduces power loss and signal reflections. The network balance input, NETBAL, of the interface's 2-wire to 4-wire convertor circuitry provides selection of a 600 balance, used when feeding channel banks or when performing external tests on the trunk circuit, or the AT&T compromise. When the NETBAL input pin is grounded, the interface balance against the AT&T Preliminary Information compromise network consisting of 350 plus 1k shunted by a 0.21F capacitor. This is typical of North American C.O. connections. The Tip and Ring also provide the balanced input to the signal detection circuitry which generates the signalling status outputs TG, RC, RV, FC and RG. For Ground Start signalling, relay K2 and resistor R1 and R2, are required. Activation of K2 is controlled by the relay control logic input signal, RC2. In the idle state, K2 is closed connecting the -48 VDC supply Tip and Ring through biasing resistors R1 and R2. Upon detection of TG or RG, the system then pulls RC1 low, closing K1, then pulls RC2 low which opens K2 to remove the -48 volts supply from Tip and Ring. In the Ground Start signalling environment, initiating a call to the C.O. is performed by the following sequence of events. The system provides a logic low on the ring ground input pin of the interface. This activates the circuitry which grounds the ring lead through a current limiting resistance. The C.O. recognizes the ground condition and connects the tip lead to ground. The interface senses this condition and the tip lead ground detect output switches to a logic low. The system then applies active line termination by closing K1 using RC1 and opens K2 using RC2. A call from the C.O. can be performed similarly. The C.O. can signal to the interface by pulling either Tip or Ring to ground potential, or by applying ringing voltage to the Ring lead. Signal Detection Circuitry The signal detection circuitry provides the signalling status outputs. The system, controlling the interfaces, monitors these active low logic outputs. RV is the Ringing Voltage detect outputs. When the C.O. applies ringing voltage to the termination, the trunk interface provides a 50ms debounced output at RV during the ringing burst period. This output will remain low for approximately 50ms after C.O. removes the ringing Voltage. Ringing voltage above 40 VRMS at 20Hz will be detected. TG is the Tip lead Ground detect output and RG is the Ring lead Ground detect output. The TG and RG outputs provides a means of determining call original or other hand shaking functions. The high impedance detection circuitry of the interface will detect both Tip and Ring Ground voltages above approximately -15.3V of true ground. RC is the Reverse Loop Current detect output and FC is the Forward Loop Current detect output. 2-228 Preliminary Information The RC and FC outputs of the interfaces are used to determine the polarity of the Tip and Ring pair which the C.O. uses for signalling during the active (off-hook) state of the interface. When the loop is closed by the interface, the trunk is in the normal or unreversed state. Some C.O.'s may reverse the polarity of Tip and Ring, to indicate the talking state. The interface will detect this condition and RC will output a low level. MH88631 and Ring inputs of the interface, following by metal oxide varistors from Tip and Ground, Ring to Ground and Tip to Ring. Components List (for Figure 3) R1*, R2* R4 = 30.9k, 1% 1/4W = Transmit Gain Adjust Resistor = 301.5 E3x Gain VX - 100 E3 VTR Typical Value = 200k, 1% 1/4W = Receive Gain Adjust Resistor = 523.2 E3 x Gain VTR VR External Circuitry Requirements R3 The loop seize circuit is completed with the addition of external components Q1, C5, R5 and K1. K1, a DPST reed relay, is activated by relay control signal RC1. When the loop seizure is required, K1 is closed and the interface applies active termination across Tip and Ring. The relay should have a 0.5 amp contact capability and 12 VDC operation with a typical 500 coil resistance. To prevent back EMF from damaging the relay drive transistor, (caused by the collapsing field of the inductive coil of the relay) a snubbing diode is provided on the hybrid and therefore not required externally. C5 and R5 provide relay contact noise filtering and transient noise suppression necessary for clamping inductive spikes created when the loop is closed during line seizure or dial pulsing. Q1 provides current drive for the active termination, controlling the loop current flow of the current modulator circuitry. Selection of a suitable transistor for Q1 is made based on worst case conditions which include fault conditions. A 350 volt, or higher, rating for Q1 is necessary to meet high voltage requirements. The Tip and Ring input protection varistors limit any high voltage spikes to approximately 300 volts. Under worst case conditions Q1 must be able to handle close to 100mA of collector current and dissipate two watts continuously. During pulse dialling, current spikes are generated due to the inductive nature of the loop. A 0.5 amp continuous connector current rating is therefore recommended to provide a safe margin. K2, R1 and R2 are required only for Ground Start applications. K2 is the same type of relay as K1 and is activated by RC2. Once again the snubbing diode is provided on the hybrid. R1 and R2 provide the -48V biasing the signalling (on-hook) state. R6 and C6 constitute the Dummy Ringer required for the LS/GS trunk. These components are also part of the 600 input impedance. Protection circuitry on the Tip and Ring inputs may be required depending upon the trunk interface application. For maximum protection it is recommended to place fuses in series with the Tip Typical Value = 505k, 1%, 1/4W R5 = 510, 5%, 1/4W R6 = 10k, 5%, 1/4W C1, C2, C3, C4= 0.22F, 10%, 200V C5 = 0.1F, 5%, 250V C6 = 1.0F, 5%, 250V Q1 = 2N5657, NPN 350V, 0.5A, 20W K1, K2 = 2A Reed Relay, E/M 12V 2 Form C Dip *Note: required for Ground Start applications, not required for Loop start applications. 2-229 MH88631 Absolute Maximum Ratings* Parameter 1 DC Supply Voltage Sym VDD - GNDD VEE - GNDD VCC + -GNDA VCC - GNDA TSTG Preliminary Information Min -0.3 -0.6 +18.0 -55 Max +6.0 +0.3 +18.0 +125 Units V V V V C 2 Storage Temperature * Exceeding these values may cause permanent damage. Functional operation under these conditions is not implied. Recommended Operating Conditions Parameter 1 Operating Supply Voltage Sym VDD VEE VCC+ VCC VBat IDD IDD IDD IDD PC TOP 0 Typ* 4.75 -5.25 11.4 -11.4 Min 5.0 -5.0 12.0 12.0 -48 Max 5.25 -4.75 12.6 -12.6 6.0 -6.0 8.0 -8.0 265 70 Units V V V V V mA mA mA mA mW C RINGND high Comments 2 Operating Current 3 4 Power Consumption Operating Temperature * Typical figures are at 25 C with nominal + 5V supplies for design aid only. DC Electrical Characteristics Characteristics 1 2 3 4 Input High Voltage Input High Current Input Low Voltage Input Low Current RC1, RC2 RINGND RC1, RC2 RINGND RC1, RC2 RINGND RC1, RC2 RINGND Sym VIH IIH Min 2.7 4.5 2.5 Typ* Max Units V V Test Conditions 5.0 -100 0.7 mA A V A mA VIL IIL 1.0 1.1 DC Electrical Characteristics are over recommended operating conditions unless otherwise stated. * Typical figures are at 25C with nominal +5V supplies and are for design aid only. Control Inputs State Table Parameter 1 2 3 4 RC1 RC2 RINGND NETBAL AT&T compromise network (350 + 1k/0.2F) 600 network Active Logic high Logic High Logic Low AGND Open (no connection) Idle Logic Low Logic Low Logic High 2-230 Preliminary Information AC Electrical Characteristics Characteristics 1 2 Ringing Voltage Ringing Frequency -1 version -2 version 3 4 5 6 7 8 Operating Loop Current Off-Hook DC Resistance Operating Loop Resistance On-Hook Leakage Current Ring Ground Sink Current Tip and Ring AC Impedance IRG 600 IL RT RL 3 100 18 Sym VR Min 40 Typ* 90 20 50 70 300 2300 Max 130 Units Vrms Hz Hz mA m MH88631 Test Conditions Voltage range 40 -120Vrms Voltage range 35 -120Vrms @18mA @18mA RINGND = 5.0Vdc -48VDC with 200 in series on Ring lead with 1.0k + 1.0F in parallel with Tip and Ring 200-1000Hz 1000-4000Hz 200-1020Hz 1020-3020Hz 200-500Hz 500-1000Hz 1000-340Hz 200Hz 1000Hz 3000Hz 200-1000Hz 1000-4000Hz 200Hz 300Hz 3000Hz 3400Hz See Note 1 C-Message 9 Longitudinal Balance metallic to longitudinal longitudinal to metallic 60 40 58 53 20 26 30 THL 18.5 34 30 18 20 -0.15 -0.10 -0.10 -0.15 8 PSR R 40 6 0.05 0.05 0.05 0.05 dB dB dB dB dB dB dB dB dB dB dB dB dB dB dB dB dBrnco dB dBm 10 Return Loss Trunk to Line 11 Transhybrid Loss (single frequency) into 600 Transhybrid Loss (single frequency) into AT&T Compromise Frequency response (Output relative to 1kHz, VTR/VR and VX/VTR) 12 13 THL 14 15 16 Idle channel noise Power Supply rejection ratio Analog signal overload level (adjustable gain) 1kHz,0dBm = 0.775Vrms into 600 * Typical figure are at 25C with nominal 5V supplies and are for design aid only Note 1: Input 0dBm at VTR, or input 0.0775Vrms at VR. TR=600 Termination. DC Electrical Characteristics Characteristics 1 2 3 4 Output High Voltage (TG, RC, RV, FC, RG) Output High Current (TG, RC, RV, FC, RG) Output Low Voltage (TG, RC, RV, FC, RG) Output Low Sink Current (TG, RC, RV, FC, RG) Sym Min Typ* 4.75 0.17 -0.30 -0.40 Max Units V mA V mA Test Conditions No Load on output VOH=-2.7Vdc No Load on output VOL=-0.4Vdc * Typical figure are at 25C with nominal 5V supplies and are for design aid only 2-231 MH88631 Preliminary Information MH88631-1, -2 DUMMY RINGER TIP LIGHTNING PROTECTION RING R1 K2A R2 11,30 K2B AGND R6 C6 5 R RXINRXOUT GSR XB XC 13 24 26 21 8 R3 K1A 4 VTRT TXIN+ RXIN+ 6 29 12 C2 C3 C1 -48V RETURN 1 LPGND -48V BATTERY Loop Current Setting 33 RGND 40 39 38 K1 37 35 16 17 18 19 15 RC2 RD2 CD RD1 RC1 RC RV FC RG TG VDD XA 9 K1B C4 C5 Q1 R5 +12V K2 27 TXIN 7 VTR+ 20 QB 10 QE NETBAL RINGND VR VX GSX 36 3 31 32 34 R4 VEE VCC+ VCC25 28 2,23 22,14 +5V -5V +12V -12V Figure 3 - Application Circuit 2-232 Preliminary Information MH88631 Side View 0.140 Max (3.6 Max) 4.00 + 0.03 (102 + 1.0) 0.60 Max (15.25 Max) 1234 39 40 0.010 + 0.002 (0.25 + 0.05) 0.14 Max (3.6 Max) * 0.05 + 0.01 (1.3 + 0.5) * 0.05 + 0.02 (1.3 + 0.05) 0.020 + 0.05 (0.51 + 0.13) * * Notes: 1) Not to scale 2) Dimensions in inches). 3) (Dimensions in millimetres). *Dimensions to centre of pin & tolerance non accumulative. 0.18 + 0.02 (4.6 + 0.5) 0.100 + 0.10 (2.54 + 0.13) Figure 4 - Mechanical Data 2-233 MH88631 Notes: Preliminary Information 2-234 |
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