™ Le5712 Dual Subscriber Line Interface Circuit VE580 Series APPLICATIONS DESCRIPTION Ideal for low-cost, high performance line card applications (CO, DLC) Meets requirements for countries such as: India, China, Korea, Japan, Taiwan, and Australia Meets requirements for North America DLC applications (TR-57-CORE) FEATURES Dual-Channel SLIC device with small footprint Loop start and Ground start support +5 V and battery supply required Optional dual battery operation –39 to –60 V battery operation Supplies more than 20 mA into 2000 Ω from –48 V Programmable current limit On-chip Thermal Management (TMG) feature in all Active states Low standby power (24 mW per channel) Supports 2.0 Vrms metering applications Control states: Active and Active Metering (Normal and Reverse Polarity), Standby, Tip Open and Disconnect 3.3-V compatible to logic control inputs The innovative Le5712 dual-channel SLIC device is designed for high-density POTS applications requiring a small-footprint, low-power SLIC device. By combining a fully featured line interface of two channels into one SLIC device, the Le5712 device enables the design of a low-cost, high performance, and fully programmable line interface for multiple country applications worldwide, including Ground Start and metering capability. The on-chip Thermal Management (TMG) feature allows for significantly reduced power dissipation on the device. Optional dual battery operation to reduce total power consumption is also available. The device is offered in a thermally efficient, space-saving 44-pin eTQFP package. The 12 x 12 mm footprint allows designers to make a dramatic increase in the density of lines on a board. The Le5712 device is also designed to significantly reduce the number of external components required for line card design. Zarlink offers a range of compatible SLAC™ devices that perform the codec function in a line card. In particular, the Zarlink Quad and Octal SLAC devices combined with the Le5712 device provides a programmable line circuit that can be configured for varying requirements. RELATED LITERATURE 081110 Thermal Management for the Le5711 and Le5712 SLIC Devices Application Note 080900 Le5711 and Le5712 Comparison Brief Power up in Disconnect state Application Note On-hook transmission in Active states Per-channel fault detection and indication Per-channel thermal shutdown Programmable Off Hook and Ground Start thresholds. Programmable ring-trip detect threshold 080753 Le58QL02/021/031 QLSLAC™ Data Sheet 080754 Le58QL061/063 QLSLAC™ Data Sheet 080921 Le58083 Octal SLAC™ Data Sheet 080676 Le5711 Dual SLIC Data Sheet Footprint compatible with Zarlink’s Le5711 Dual SLIC FLT 1 C3 1 C2 1 C1 1 DET 1 RD CAS IREF C1 2 DET 2 C3 2 Tray TMG 1 CH1 2-W Interface CH1 CH1 CH1 HP 1 CH1 Signal Transmission CH2 Power Feed Controller CH2 Off-Hook & Ground Start Detector RSN 2 CH2 Ring Trip Detector CH2 VTX 2 AD 1 BD 1 BD 2 Ring Trip Detector BGND 2 VTX 1 RSN 1 Document ID# 081047 Date: Rev: G Version: Distribution: Public Document AGND/ DGND CDC 1 VCC BGND 1 DB 1 For delivery using a tape and reel packing system, add a "T" suffix to the OPN (Ordering Part Number) when placing an order. CH1 Input Decoder and Control Common Bias DAC 2. HP 2 CH2 2-W Interface DB 2 The green package meets RoHS Directive 2002/95/EC of the European Council to minimize the environmental impact of electrical equipment. AD 2 Off-Hook & Ground Start Detector 1. CH2 Input Decoder and Control TMG 2 VBREF 44-pin eTQFP (Green), –63 dB, Reverse Polarity CH1 Fault Detector Power Feed Controller Le57D122BTC CH2 Fault Detector CDC 2 Le57D121BTC 44-pin eTQFP (Green), –53 dB, Reverse Polarity Packing2 Signal Transmission Package Type1 VBAT Device FLT 2 ORDERING INFORMATION C2 2 BLOCK DIAGRAM 120402 Sep 18, 2007 2 Le5712 Data Sheet TABLE OF CONTENTS Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Description. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Related Literature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Product Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3 Block Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3 Two-Wire Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3 Signal Transmission . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4 Power Feed Controller and Common Bias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4 Input Decoder and Control. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 Device State Decoding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 Off-Hook Detector (OHD) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 Ground Start Detector (GSD) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 Ring-Trip Detector . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 Fault Detector . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 Thermal Shutdown. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 Connection Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 Pin Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8 Operating Ranges . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8 Environmental Ranges . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8 Electrical ranges . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9 Summary of Test Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9 Supply Currents and Power Dissipation (on-hook) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9 Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9 Device specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9 DC Feed Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14 Test Circuits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15 POTS Application Circuit (POTS with no metering). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18 Application Circuit Parts List (Pots with no metering) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .19 Pulse Metering Application Circuit (Pots with metering) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .20 Application Circuit Parts List (Pots with metering) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21 Physical Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22 Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23 Revision C1 to D1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23 Revision D1 to E1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23 Revision E1 to F1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23 Revision F1 to G1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23 Revision G1 to G2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23 2 Zarlink Semiconductor Inc. Le5712 Data Sheet PRODUCT DESCRIPTION The Le5712 device is designed for long loop high-density POTS applications requiring a low power, small footprint SLIC device. The Le5712 device increases line card density by integrating two SLIC devices into a single 44-pin package. This reduction in board space permits a higher density line card, which allows for amortizing common hardware across more channels. The Le5712 device gives line card designers a simple control interface that supports seven states: Active, Active Metering, Reverse Polarity, Reverse Polarity Metering, Standby, Tip Open and Disconnect (Ringing). The low cost and high performance Le5712 device provides the key features for POTS markets requiring loop start, loop start and metering, or ground start. The device includes a thermal management feature for minimizing power dissipation on the SLIC. Alternatively, the device can be operated in a dual battery configuration to reduce overall power consumption. BLOCK DESCRIPTIONS Two-Wire Interface The two-wire interface provides DC current and sends voice and signalling information to a customer premise equipment. The two-wire interface also receives the returning signals from the customer premise equipment. This block implements the thermal management feature, which allows power that would otherwise be dissipated within the package to be off loaded into an external resistor when the line is Off Hook. RTMGi is connected from TMGi to the VBAT pin and limits power within the SLIC device (Note: "i" denotes channel number). The minimum value of RTMGi is given by: BAT MAX – 6 – I LIMITMIN ⋅ ( 2 • R F + R LMIN + 40Ω ) R TMG ≥ ---------------------------------------------------------------------------------------------------------------------------------I LIMITMIN – 3 mA where ILIMITMIN is the minimum programmed loop current limit and RLMIN is the minimum loop resistance. The tolerance of RTMG should be taken into account when selecting a value that meets this requirement. For example, if BATMAX = -56 V, ILOOPMIN = 30 mA and RLMIN = 200 Ω then RTMG = 1.5 kΩ is the minimum recommended value. A value of 1.8 kΩ with 5% accuracy will keep the power in RTMG below 1.0 W, and the total worst case SLIC power dissipation with both channels active below 1.6 W. The power dissipated in the TMG resistor is given by: 2 ( BAT – 5 – I L • ( R L + 2R F + 40 ) ) P RTMG = -----------------------------------------------------------------------------------------R TMG where IL is the loop current, and RL is the loop resistance. The maximum power on RTMG is given by: 2 ( BAT max – 5 – I LIMITmin ( R Lmin + 2R F + 40 ) ) P RTMGmax = --------------------------------------------------------------------------------------------------------------------------R TMGmin And the power dissipated per channel in the SLIC device while in the Active states is given by: I P SLICi = 0.003 BAT + ( BAT – 3 – I L ( R L + 2R F + 40 ) ) I L – --------------- ( BAT – 5 – I L ( R L + 2R F + 40 ) ) R TMG The maximum power dissipated per channel in the SLIC device while in the Active states is given by: I LIMITmax P SLICmaxi = 0.003 BAT max + 1 + ------------------------- R TMGmax 2 I LIMITmax 1 ------------------------ + ----------------------- 2 R TMGmax Refer to the Thermal Management for the Le5711 and Le7512 Dual SLIC Devices Application Note for further analysis and for dual battery condition. The AC signal swing supported by the two-wire interface is controlled by the SLIC state. For standard voice transmission, the Active and Reverse Polarity states are used. To support voice plus meter pulses, the Active Metering and Reverse Polarity Metering states are provided which have increased overhead to support 2.0 Vrms metering. 3 Zarlink Semiconductor Inc. Le5712 Data Sheet Signal Transmission The RSNi input current controls the receive current sent to the two-wire interface. The AC line voltage is sensed by a differential amplifier between the ADi and HPi leads. The output of this amplifier is equal to the AC metallic components of the line voltages and is output at VTXi. The desired two-wire AC input impedance, Z2WIN, is defined by the fuse resistors, RF, and an impedance connected from VTXi to RSNi, ZTi. When computing ZTi, the internal current amplifier pole and any external stray capacitance between VTX and RSN must be taken into account. 500 Z Ti = --------- ⋅ ( Z 2WIN – 2R F ) 3 To set the desired receive gain (G42L) into a load ZL from VRXi, ZRXi is connected from VRXi to RSNi, where ZL 500 • Z T Z RXi = ------------- • --------------------------------------------------G 42L 500 Z T + --------- ( Z L + 2R F ) 3 The transmission block also contains a longitudinal feedback circuit to shunt longitudinal signals to a DC bias voltage. The longitudinal feedback does not affect metallic signals. Two application circuits, provided at the end of this data sheet, show how the Le5712 device can connect directly to pins of a QLSLAC codec. The POTS Application Circuit (POTS with no metering), on page 18 shows an application providing Loop Start and Ground Start capability. The components selected for the transmission network allow a wide range of market transmission requirements to be met when combined with the programmable QLSLAC device. In addition, transmit relative levels of Li = +4 to -4 dBr and receive relative levels of Lo = 0 to -8dBr can be supported using only the digital gain within the QLSLAC device for all markets. This configuration will meet ITU Q.552 and GR57 requirements. The Pulse Metering Application Circuit (Pots with metering), on page 20 shows a configuration for use in a 12 or 16 kHz pulse metering application with the QLSLAC device. The design allows 2 Vrms into 200 Ω, and supports gain ranges of at least Li = 0 to +4dBr, and Lo = 0 to -8 dBr. This configuration will meet ITU Q.552 requirements over these gain ranges for markets such as India and China. The relationship between metering source VM, the feeding resistance, RM, and the output voltage at tip-ring, VTR, is given in the following equation. The load at tip-ring is RM. RF is the protection and other, if any, front-end resistances. ZT is the impedance between VTX and RSN at metering frequency. ZM 500 - • ------------------------------------------------- V M V TR = ------Z M + 2R F RM 500 1 + --------- • -----------------------3 ZT Metering signal at VTX needs to be filtered to prevent from overloading the codec. This has been realized in the applications circuitry in this document. Power Feed Controller and Common Bias The power feed controllers have three sections: (1) the common bias circuit, (2) the battery feed circuit, and (3) the reverse polarity circuit which operate in all Active states. The bias circuit provides a signal which sets the current limit and creates a voltage related to VBAT, filtered by a capacitor connected to the CAS pin, to the battery feed circuit. 470 The nominal current limit is set by the following equation: I -------------LIMIT = R REF 1 A recommended 3 Hz filter pole frequency (fc) can be implemented from: C CAS = ----------------------------------------RI AS • 2 • π • f c The battery feed circuit regulates the amount of DC current and voltage supplied to the telephone over a wide range of loop resistance. It is designed to operate over a nominal 22 to 33 mA range of programmed current limit. It produces a filtered reference voltage offset from the subscriber line voltage which is applied to the two-wire interface. In addition, a low pass filter is implemented with a capacitor connected to the CDCi pin. In the low power Standby state, an alternative feed is implemented via two current limited on chip 200-Ω resistors. The nominal loop current below current limit in the Standby state is given by: V BAT – 4 V I STANDBY = ------------------------------600 Ω + R L 4 Zarlink Semiconductor Inc. Le5712 Data Sheet Input Decoder and Control The input decoder and control block provides a means for a microprocessor or SLAC device IC to control such system states as Active, Active Metering, Reverse Polarity, Reverse Polarity Metering, Standby, Tip Open and Disconnect (Ringing). The input decoder and control block has TTL-compatible inputs, permitting interfacing to 5 or 3.3 V VCC controllers which set the operating states of the SLIC device. It also provides the loop supervision signal sent back to the controller. From power up, the device is in disconnect state unless over-written by external control inputs. Device State Decoding (For channel i = 1 or 2) State C3i C2i C1i Two-Wire state DETi output 0 0 0 0 Reserved N/A 1 0 0 1 Active Metering OHD 2 0 1 0 Tip Open GSD 3 0 1 1 Reverse Polarity Metering OHD 4 1 0 0 Disconnect RTD 5 1 0 1 Active OHD 6 1 1 0 Standby OHD 7 1 1 1 Reverse Polarity OHD Off-Hook Detector (OHD) The On-to-Off-hook and Off-to-On-hook detections are based on loop current and are defined as |IAD - IBD| / 2. The On-to-Offhook (OHD) and Off-to-On-hook (OND) thresholds are programmed with the RD resistor and the threshold applies to all Active and Standby states. 935V I OHD = ------------RD I OHD = I OND + Hysteresis Upon the loss of battery the DET pin will be HIGH. Off-hook detection or DET state should be ignored during on-hook metering. Ground Start Detector (GSD) This detector is active in the Tip Open state. The threshold, IGSD, is defined by the same equation used for the OHD. For ground start lines, the device is in the Tip Open state between calls. When a ring ground condition is detected, the device should be switched to the Active state. During this period, the DET pin will be active if the ring to ground current is greater than twice the IOHD threshold. The DET pin will go active once the ring ground is removed and a loop is applied. It is recommended that a firmware time-out period is applied in case the call attempt is abandoned and DET never goes low. The time-out is reset once an active DET is seen in the Active state. Ring-Trip Detector In the Disconnect state, the ring-trip detector is active. While the DBi pin is more negative than the DAC pin, the DET pin will be High to indicate on hook. When an off hook condition occurs, the DBi pin becomes more positive than the DAC pin, and the DET pin will go Low to indicate off hook during ringing (ring-trip) has been detected. The system implements the Ringing state using external control of a ring relay in combination with the Disconnect SLIC device state, which enables the ring-trip detector. The POTS Application Circuit (POTS with no metering), on page 18 shows a ring trip bridge configured and components are selected for a typical battery-backed ringing applications such as for the US (TR-57) and China (GF002). The Pulse Metering Application Circuit (Pots with metering), on page 20 shows a ring trip bridge configured and components are selected for a typical earth-backed ringing applications such as in India (G/LLT and G/MLT). Fault Detector The DSLIC device provides a fault detection function in the Active states on each channel. Under a fault condition the detector senses longitudinal voltage at tip and ring and flags a fault by pulling the FLTi pin Low. The FLTi pins are compatible with logic outputs, and may be monitored to clearly identify a fault condition from a loop condition. In case of low level longitudinal AC induction the FLTi may pulse at twice the frequency of the induction signal. Upon the loss of battery the FLT pin will be LOW. 5 Zarlink Semiconductor Inc. Le5712 Data Sheet Thermal Shutdown. Thermal shutdown is provided on a per channel basis to protect the die from excessive temperature. Persistent faults will produce high power dissipation, and may result in the affected channel triggering its thermal shutdown detector (Minimum > 145º C). At this point the power amplifiers are turned off and the device is in a disconnect like state, FLT and DET will be active. The thermal shutdown detector has approximately 10º C of hysteresis. Thermal shutdown on one channel will not affect the operation of the other channel. The thermal performance of a thermally enhanced package is assured through optimized printed circuit board layout.The thermal pad at the bottom of the package should be soldered down to printed circuit board. Refer to the Thermal Management for the Le5711 and Le7512 Dual SLIC Devices Application Note for details. TMG 1 HP 1 NC FLT 1 VBREF NC VTX 1 NC RSN 1 CDC 1 DET 1 CONNECTION DIAGRAM 44 43 42 41 40 39 38 37 36 35 34 C21 1 33 BGND 1 C11 2 32 BD 1 C3 1 3 31 AD 1 AGND/DGND 4 30 DB 1 VCC 5 29 DAC RD 6 28 NC CAS 7 27 VBAT IREF 8 26 DB 2 C12 9 25 AD 2 C22 10 24 BD 2 DET 2 11 23 BGND 2 44-Pin eTQFP Exposed Pad TMG 2 HP 2 NC FLT 2 NC NC VTX 2 NC RSN 2 C3 2 CDC 2 12 13 14 15 16 17 18 19 20 21 22 120402 Note: 1. Pin 1 is marked for orientation. 2. NC = No Connect 3. The exposed heat sink pad on the bottom of the eTQFP package should be connected to VBAT pin - the SLIC side of the diode from battery supply. Do not connect it to GND. 6 Zarlink Semiconductor Inc. Le5712 Data Sheet PIN DESCRIPTIONS Pin Name Type AD1 Output Description Output of AD power amplifier of channel 1. AD2 Output Output of AD power amplifier of channel 2. AGND/DGND Ground Analog and digital ground. Output of BD power amplifier of channel 1. BD1 Output BD2 Output Output of BD power amplifier of channel 2. BGND1 Ground Battery (power) ground of channel 1 BGND2 Ground Battery (power) ground of channel 2. C11/C21/C31 Input C12/C22/C32 Input State decoder inputs of channel 1. CAS Capacitor Pin for capacitor to filter reference voltage when operating in anti-saturation region. CDC1 Capacitor DC feed filter capacitor of channel 1. CDC2 Capacitor DC feed filter capacitor of channel 2. FLT1 Output Channel 1 fault detector output1. FLT2 Output Channel 2 fault detector output1. DAC Input Ring-trip negative of both channels. Negative input to ring-trip comparator. DB1 Input Ring-trip positive of channel 1. Positive input to ring-trip comparator. DB2 Input Ring-trip positive of channel 2. Positive input to ring-trip comparator. State decoder inputs of channel 2. DET1 Output DET2 Output HP1 Capacitor HP2 Capacitor Connect a High-Pass filter capacitor in series with a resistor from HP2 to BD2. Resistor Connection for reference resistor that programs Off Hook Detector threshold and DC feed current limit of both channels. IREF NC — RD Resistor Off Hook / Ring-trip detector output of channel1. Logic low indicates that a detector is tripped. Off Hook / Ring-trip detector output of channel 2. Logic low indicates that a detector is tripped. Connect a High-Pass filter capacitor in series with a resistor from HP1 to BD1. No Connect. This pin is not internally connected. Connection for resistor that programs off hook detector threshold of both channels. Input Receive Summing Node of channel 1. In the Active and Reverse Polarity states, the current (both AC and DC) between AD1 and BD1 is equal to 500 times the current into this pin. The networks that program receive gain, metering gain and two-wire impedance of Channel 1 connect to this node. RSN2 Input Receive Summing Node of channel 2. In the Active and Reverse Polarity states, the current (both AC and DC) between AD2 and BD2 is equal to 500 times the current into this pin. The networks that program receive gain, metering gain and two-wire impedance of Channel 2 connect to this node. TMG1 Output Thermal management of channel 1. External resistor connects from TMG1 to VBAT to off-load power from the SLIC device. TMG2 Output Thermal management of channel 2. External resistor connects from TMG2 to VBAT to off-load power from the SLIC device. VBAT Battery Battery supply and connection to substrate. Connect to highest negative supply with a diode on a per line base. RSN1 VBREF Input This is a Zarlink reserved pin and must always be connected to the VBAT pin. VCC Power +5 V power supply. VTX1 Output Transmit audio signal of channel 1. This output is a scaled version of the A and B metallic voltage. VTX1 also sources the two-wire input impedance programming network. VTX2 Output Transmit audio signal of channel 2. This output is a scaled version of the A and B metallic voltage. VTX2 also sources the two-wire input impedance programming network. EPAD Battery The exposed heat sink pad on the bottom of the eTQFP package should be connected to VBAT pin - the SLIC side of the diode from battery supply. This thermal pad should also be soldered down to printed circuit board to achieve the desired package thermal performance. Note: 1. Consult Zarlink representatives for proper handling when not in use. 7 Zarlink Semiconductor Inc. Le5712 Data Sheet ABSOLUTE MAXIMUM RATINGS Stresses greater than those listed under Absolute Maximum Ratings can cause permanent device failure. Functionality at or above these limits is not implied. Exposure to absolute maximum ratings for extended periods can affect device reliability Storage temperature VCC with respect to AGND / DGND –55 to +150º C –0.4 to +7.0 V VBAT with respect to AGND / DGND +0.4 to –63 V BGND1, BGND2 with respect to AGND / DGND +3 to –3 V AD1, AD2, BD1, BD2 with respect to BGND: VBAT to + 1 V Continuous 10 ms (F = 0.1 Hz) 1 µs (F = 0.1 Hz) 250 ns (F = 0.1 Hz) Current from AD1, AD2, BD1, BD2 –70 to +5 V –80 to +8 V –90 to +12 V ±150 mA DB1, DB2, and DAC inputs: VBAT to 0 V Voltage on ring-trip inputs Current into ring-trip inputs C11, C21, C31, C12, C22, C32 ±10 mA Input Voltage Maximum power dissipation in 44-pin eTQFP TA = 70º C, continuous –0.4 to VCC + 0.4 V (see note 1) Thermal Data in 44-pin eTQFP package Junction to Ambient, θJA (see note 2) ESD Immunity (Human Body Model) JESD22 Class 1C compliant Notes: 1. 2. Thermal limiting circuitry on chip will shut down the circuit at a junction temperature of about 165º C. Continuous operation above 145º C junction temperature may degrade device reliability. Refer to the Thermal Management for the Le5711 and Le7512 Dual SLIC Devices Application Note for details. The thermal performance of a thermally enhanced package is assured through optimized printed circuit board layout. Refer to the Thermal Management for the Le5711 and Le5712 Dual SLIC Devices Application Note for details. Package Assembly Green package devices are assembled with enhanced, environmental compatible lead-free, halogen-free, and antimony-free materials. The leads possess a matte-tin plating which is compatible with conventional board assembly processes or newer leadfree board assembly processes. The peak soldering temperature should not exceed 245°C during printed circuit board assembly. Refer to IPC/JEDEC J-Std-020B Table 5-2 for the recommended solder reflow temperature profile. OPERATING RANGES The operating ranges specified below define those limits between which the device operates and is guaranteed under the noted test conditions. (Refer to Summary of Test Conditions, on page 9.) Environmental Ranges Zarlink guarantees the performance of this device over commercial (0 to 70º C) and industrial (−40 to 85º C) temperature ranges by conducting electrical characterization, production testing, and periodic sampling over each range. These characterization and test procedures comply with section 4.6.2 of Bellcore GR-357-CORE Component Reliability Assurance Requirements for Telecommunications Equipment. −40° to 85°C 15% to 85% Ambient Temperature Ambient Relative Humidity Electrical ranges VCC 4.75 to 5.25 V –39 to –60 V VBAT to –2 V VBAT DB1, DB2, and DAC AGND BGND1, BGND2 with respect to AGND/DGND 0V –100 to + 100 mV Load resistance on VTX1, VTX2 to ground 8 kΩ minimum 8 Zarlink Semiconductor Inc. Le5712 Data Sheet ELECTRICAL CHARACTERISTICS Summary of Test Conditions Unless otherwise noted, the test conditions are defined by the Le5712 device test circuit shown in Figure 7, on page 17 with: VCC=5 V, BAT = -52 V, RL = RLAC = 600 Ω, RREF = 14.3 kΩ, RD = 82.5 kΩ. Supply Currents and Power Dissipation (on-hook) ICC mA (Note 1.) Operational State Min. Typ IVBAT mA (Note 1.) Max Min. Typ SLIC Device Power mW Max Min. Typ Max Disconnect 3.2 5.5 0.5 0.8 42 62 Standby 3.2 6.5 0.6 1.0 46 70 Tip Open 3.1 6.5 0.6 1.0 46 70 Active 9.0 13 6.0 10.0 353 540 Reverse Polarity 9.0 13 6.0 10.0 353 540 Active Metering 9.3 13 6.0 10.0 355 540 Reverse Polarity Metering 9.3 13 6.0 10.0 355 540 One channel Standby One channel Active 6.1 10 3.3 5.5 200 305 Note 2 SPECIFICATIONS Device specifications Specification Condition Min. Typ Max Active 42.75 45.7 48 Standby 46.75 42.5 Unit Note Line Characteristics VAB, Open Circuit 52 V Metering states 38 41.5 IL, Long Loops, Active state RLDC= 2000 Ω, BAT = -48 V 20 20.5 ILIMIT, Short Loops, Active state RLDC= 100 Ω to 1100 Ω 30 33 IL, Long Loops, Active state RLDC= 2125 Ω 20 21.1 mA IL, Long Loops, Active state RLDC= 2125 Ω, BAT = -46.5 V 18 18.5 mA 0.9IL IL 20 30 45 85 120 mA µA IL, Accuracy, Standby state BAT – 4V I L = ------------------------------ , R LDC ≥ 2000Ω ( RL + 600 ) Current Limited Region ILLIM, AD and BD to BGND Active, IAD + IBD mA 36 1.1IL mA 3 mA IL, Loop current, Disconnect state RL = 0 Ω 100 IAD leakage, Tip Open state RL = 0 Ω 100 µA IBD current, Tip Open state BD to BGND 45 mA VAD Active and Standby states AD to BAT=7 kΩ, BD to GND=100Ω 20 30 -7.5 -5 VIREF, IREF pin output voltage 1.2 1.25 1.3 V K1, Incremental RSN current gain 490 500 510 A/A V Power Supply Rejection Ratio at the Two-Wire Interface (Active states, On or Off Hook) VCC 50 Hz to 3.4 kHz VRIPPLE = 100 mVrms VBAT 300 Hz to 3.4 kHz VRIPPLE = 100 mVrms RIAS, Effective internal resistance 30 40 28 50 50 Hz to 60 Hz 20 CAS pin to AGND 90 9 Zarlink Semiconductor Inc. 150 210 dB 4 kΩ 2 Le5712 Specification Condition Data Sheet Min. Typ Max Unit Note –63 -67 dB –60 -64 dB –60 -67 dB 2 –57 -64 dB 2 Longitudinal Capability (See Figure 4, on page 16.) Longitudinal to metallic L-T balance Normal polarity 200 Hz to 1.0 kHz, Le57122 0º C to +70º C Longitudinal to metallic L-T balance Normal polarity 3.0 kHz, Le57122 0º C to +70º C Longitudinal to metallic L-T balance Normal polarity 200 Hz to 1.0 kHz, Le57122 -40º C to +85º C Longitudinal to metallic L-T balance Normal polarity 3.0 kHz, Le57122 -40º C to +85º C Longitudinal to metallic L-T balance 0º C to +70º C –53 -40º C to +85º C –50 Longitudinal signal generation 4-L 200 Hz to 3.4 kHz 40 dB Longitudinal current per pin (ADi or BDi) Active state (off hook) 8.5 mArms Longitudinal impedance at ADi or BDi 0 to 100 Hz 200 Hz to 3.0 kHz, Le57121 Longitudinal to metallic L-T balance 200 Hz to 3.0 kHz, Le57121 dB 2 5 Ω /pin 18.5 RFI Rejection (See Figure 6, on page 16.) VTX1 or VTX2 f =.01 to 100 MHz HF gen. output = 1.5 Vrms CAXi = CBXi = 33 nF 1 CAXi = CBXi = 2.2 nF 3 mVrms 2 dB 2, 6 25 Ω 2 +50 mV Transmission Performance 2-wire return loss 200 Hz to 3.4 kHz (See Figure 5, on page 16) 26 Analog output (VTX) impedance 3 Analog (VTX) output offset voltage –50 Overload level, 2-wire Active or Reverse Polarity state 2.5 Overload level, 2-wire On hook, Active or Reverse Polarity state 1.1 Overload level, 2-wire Metering states 5.5 Overload level, 2-wire On hook, Metering states 5.5 THD (Total Harmonic Distortion) 7 Vpk 7 8 0 dBm –64 –50 +7 dBm –55 –40 +9 dBm, Metering states -55 -40 THD, On hook 0 dBm, RLAC = 600 Ω –36 THD with metering RL = 300 Ω –35 Idle Channel Noise Idle Channel Noise with Metering C-Message, RL = 600 Ω Psophometric, RL = 600 Ω 8 7 12 -83 -78 Psophometric, RL = 300 Ω, -46 Metering states dB 4 2, 9 dBrnC dBmp 2 2, 10 Crosstalk Between Channels Crosstalk coupling loss Averaged over 200 Hz to 3.4 kHz, 0dBm 10 Zarlink Semiconductor Inc. 80 dB 11 Le5712 Specification Condition Data Sheet Min. Typ Max Unit Note Insertion Loss (See Figure 2 and Figure 3, on page 15.) Gain, 4-to-2-wire 0 dBm, 1 kHz –0.20 0 +0.20 Gain KTX, 2-to-4-wire 0 dBm, 1 kHz –9.74 –9.54 –9.34 Gain, 4-to-4-wire 0 dBm, 1 kHz –9.74 –9.54 Gain, 4-to-2-wire On hook –0.35 +0.35 Gain over frequency 300 to 3400 Hz, relative to 1 kHz –0.15 +0.15 Gain tracking +3 to –55 dBm, relative to 0 dBm –0.15 +0.15 Gain tracking, On hook 0 dBm to –37 dBm +3 dBm to 0 dBm –0.15 –0.35 +0.15 +0.35 Metering Gain, 4-to-2-wire VM = 0.5 vrms, 16 kHz, RL = 300 Ω 15.1 15.6 –9.34 16.1 dB 2 dB 12 Logic Interface Inputs (C11, C12, C21, C22, C31 and C32) VIH, Input High voltage 2.0 VIL, Input Low voltage 0.8 IIH, Input High current VIH=2.0V –110 IIL, Input Low current VIL=0.8V –400 90 V µA Outputs (DET1 and DET2) VOL, Output Low voltage IOUT = 0.3 mA VOH, Output High voltage IOUT = –0.1 mA 0.40 2.4 V Outputs (FLT1 and FLT2) VOL, Output Low voltage IOUT = 0.06 mA VOH, Output High voltage IOUT = –0.01 mA 0.40 2.4 V Ring-Trip Detector Input (Applies to DAC, DB1 and DB2.) Bias Current Offset voltage Source resistance = 2 MΩ –50 –10 0 nA 2 –50 0 +50 mV 13 –2 V 2 mA VBAT + 1 Common Mode Voltage Range Fault Detector (See Figure 1, on page 15.) IFAULT = |IAD + IBD| 8 11.5 20 Off-Hook and Ground Start Detectors (See Figure 1, on page 15.) IOHD On-to-Off hook Detection Threshold Active and Standby states 9.8 11.5 13.2 Hysteresis The difference between On-to-Off hook detection threshold and Off-toOn hook Detection threshold 1.3 2.0 2.7 IGSD, Ground Start Detect threshold (On-to-Off hook detection threshold) Tip Open state 11.8 13.5 16.0 Hysteresis (Ground Start) The difference between On-to-Off hook detection threshold and Off-toOn hook detection threshold 2.6 4.0 5.4 11 Zarlink Semiconductor Inc. mA Le5712 Data Sheet Notes: 1. Total current measured with both channels in the same state, unless otherwise specified. 2. Not tested in production. This parameter is guaranteed by characterization or correlation to other tests. 3. Typical current limit range is designed to be between 22 mA and 33 mA. 4. This parameter is tested at 1 kHz in production. Performance at other frequencies is guaranteed by characterization. 5. Minimum current level guaranteed not to cause a false loop detect. The fault detector may activate with longitudinal currents above 2.8 mA rms, and may pulse at twice the frequency of the interfering signal. 6. Group delay can be greatly reduced by using a ZT network such as that shown in Figure 5, on page 16 where CT = 120 pF, RTA = RTB = 50 kΩ. The network reduces the group delay to less than 2 µs and increases 2WRL. The effect of group delay on line card performance also may be compensated by synthesizing complex impedance with the QLSLAC™ or Octal SLAC™ devices. 7. Overload level is defined as THD = 1%, 8. Overload level is defined as THD = 1.5%. 9. Total Harmonic distortion with metering is specified with a metering signal of 3.0 Vrms at the two-wire output, and a transmit signal of +3 dBm or receive signal of –4 dBm. The transmit or receive signals are single frequency inputs, and the distortion is measured as the highest in band harmonic at the two-wire or the four-wire output relative to the input signal. 10. Noise with metering is measured by applying a 3.0 Vrms metering signal (measured at the two-wire output) and measuring the psophometric noise at the two-wire outputs over a 200 ms time interval 11. This is test at 1 kHz in production 12. In the test set up, ZT = 100 kΩ, RM = 16.5 kΩ, and RF = 0 Ω. The output voltage at tip/ring is expected to be 3 Vrms, into a load of 300 Ω, with 0.5 Vrms source. The typical gain is 15.6 dB. 13. Tested with 0 Ω source impedance. 2 MΩ is specified for system design only. 12 Zarlink Semiconductor Inc. Le5712 Data Sheet User-Programmable Components Summary Equation Description ZTi* is connected between the VTX and RSN pins. The fuse resistors are RF, and Z2WIN is the desired 2-wire AC input impedance. When computing ZTi, the internal current amplifier pole and any external stray capacitance between VTX and RSN must be taken into account. 500 Z Ti = --------- ( Z 2WIN – 2R F ) 3 Z RXi ZRXi* is connected from VRX to RSN. ZTi is defined above, and G42L is the desired receive gain. 500 • Z T ZL = ------------- • ------------------------------------------------------G 42L 500 Z T + --------- ⋅ ( Z L + 2R F ) 3 470 ⋅ V R REF = -----------------I LIMIT ILIMIT is the desired loop current limit in the constant-current region. 1 C CAS = ----------------------------------RI AS • 2π • f c CCAS is the regulator filter capacitor and fc is the desired filter cut-off frequency. 935 ⋅ V I OHD = I GSD = ----------------RD Off Hook Detect (IOHD) and Ground Start Detect (IGSD) thresholds are typically set at 10 to 12 mA. V BAT – 4 V I STANDBY = ------------------------------600 Ω + R L Standby loop current (resistive region). Thermal Management Equations (All Active states for one channel) (Please refer to the Thermal Management for the Le5711 and Le7512 Dual SLIC Devices Application Note for details about dual battery operation.) RTMG is connected from TMG to VBAT and limits power within the SLIC device in Active, Off-Hook states. BAT MAX – 6 – I LIMITMIN ⋅ ( 2 • R F + R LMIN + 40Ω ) R TMG ≥ ---------------------------------------------------------------------------------------------------------------------------------I LIMITMIN – 3 mA 2 ( BAT max – 5 – I LIMITmin ( R Lmin + 2R F + 40 ) ) P RTMGmax = --------------------------------------------------------------------------------------------------------------------------R TMGmin I LIMITmax P SLICmaxi = 0.003 BAT max + 1 + ------------------------- R TMGmax 2 I LIMITmax 1 ------------------------ + ----------------------- 2 R TMGmax * “i” denotes channel number 13 Zarlink Semiconductor Inc. Maximum power dissipated in the TMG resistor, RTMG, during Active, Off-Hook states. Maximum power dissipated per channel in the SLIC device while in Active, Off-Hook states. Le5712 Data Sheet DC Feed Characteristics Load Line (Active) (Typical) 50 VAB3 45 VAB2 40 |VAB| (Volts) 35 30 25 VAB1 20 15 10 On-Hook Off-Hook 5 0 0 5 10 BAT = -46.5 V 20 15 25 30 35 Loop Current (mA) BAT = -48 V BAT = -52 V RL = 2125 ohm 071902 Regions: 1. 470 V AB1 = I LOOP R L = --------------R L, where, R L = R L' + 2R F R REF Constant current region: In Active and Reverse Polarity states 2. Battery tracking anti-sat (Off-hook): 47 ⋅ kΩ ⋅ V V AB2 = BAT – 7 V + --------------------------- – I L ⋅ 160 Ω R REF 3. Battery tracking anti-sat (On-hook): 10 ⋅ kΩ ⋅ V- – I ⋅ 160 Ω V AB3 = BAT – 7 V + -------------------------L R REF In Active Metering and Reverse Polarity Metering states 4. Battery tracking anti-sat (Off-hook): ⋅ kΩ ⋅ V- – I ⋅ 160 Ω V AB2 = BAT – 10.7 V + 47 -------------------------L R REF 5. Battery tracking anti-sat (On-hook): ⋅ kΩ ⋅ V- – I ⋅ 160 Ω V AB3 = BAT – 10.7 V + 10 -------------------------L R REF 14 Zarlink Semiconductor Inc. Le5712 Data Sheet Test Circuits Figure 1. Feed Programming IAD ADi IREF RD RL DSLIC IL RREF RD IBD BDi DETi RG IG 50 pF CDC CDCi Figure 2. Two-to-Four Wire Insertion Loss VTX 1 VTX 2 AD 1, AD 2 RL DSLIC 2 VTX VAB VL RT AGND RL RRX 2 RSN 1 RSN 2 BD 1, BD 2 IL2-4 = 20 log(V TX / V AB ) Figure 3. Four-to-Two Wire Insertion Loss and Balance Return Signals VTX 1 VTX 2 AD 1, AD 2 DSLIC VAB VTX RT RL AGND RRX BD 1, BD 2 RSN 1 RSN 2 IL4-2 = 20 log(V AB / V RX ) BRS = 20 log(V TX / V RX ) 15 Zarlink Semiconductor Inc. VRX Le5712 Figure 4. 1 ωC Longitudinal Balance VTX 1 VTX 2 AD 1, AD 2 << RL RL 2 S1 Data Sheet DSLIC VTX C RT VAB AGND VL VL RL S2 2 BD 1, BD 2 RRX RSN 1 RSN 2 VRX S2 Open, S1 Closed S2 Closed, S1Open L-T Long. Bal. = 20 log(V AB / V L) 4-L Long. Sig. Gen. = 20 log(V L / V RX ) L-4 Long. Bal. = 20 log(V TX / V L x K TX ) Figure 5. Two-Wire Return Loss Test Circuit ZD = 600 Ω VTX 1 VTX 2 AD 1, AD 2 RTA DSLIC R RT 2 VM VS AGND ZIN = 600 Ω R RTB BD 1, BD 2 RT 2 CT RSN 1 RSN 2 ZD : The desired impedance; eg., the characteristic impedance of the line RRX Return loss = –20 log (2V M / V S ) Figure 6. RFI Test Circuit L1 200 Ω C1 50 Ω RF 1 200 Ω HF GEN 50 Ω AD 1, AD 2 CAD RF 2 C2 L2 50 Ω BD 1, BD 2 CBD VTX 1 VTX 2 DSLIC under test 80% amplitude modulated Modulation frequency = 1 kHz 16 Zarlink Semiconductor Inc. Le5712 Figure 7. Data Sheet Le5712 Test Circuit V CC +5V 16.5 k VM 1 150 k DB 1 BGND 1 BGND 2 DB 1 VCC C AD1 AGND RSN 1 /DGND R RX1 R T1 22 nF TIP 1 C HP1 Le5712x AD 1 CDC 1 HP 1 RING 1 VTX 1 C DC1 330 nF BD 1 C BD1 100 k VTX 1 100 nF CH1 22 nF FLT 1 R TMG1 1600 BAT VBAT R TMG2 FLT 1 DET 1 TMG 1 D VBH VRX 1 TMG 2 DET 1 C1 1 C1 1 C2 1 C2 1 C3 1 C3 1 1600 VBREF IREF VBREF RD R REF RD 16.5 k VM 2 150 k RSN 2 CAS R RX2 R T2 C CAS 0.33 µF 100 k VTX 2 DAC DAC DB 2 DB 2 VRX 2 VTX 2 CDC 2 C DC2 CH2 330 nF C AD2 FLT 2 FLT 2 AD 2 DET 2 DET 2 HP 2 C1 2 C1 2 C2 2 C2 2 C3 2 C3 2 22 nF TIP 2 C HP2 100 nF RING 2 BD 2 C BD2 22 nF 012403 17 Zarlink Semiconductor Inc. Le5712 Data Sheet POTS APPLICATION CIRCUIT (POTS WITH NO METERING) For use with a Quad or Octal SLAC device; battery-backed ringing. RING_SOURCE 75 Vrms, 20 Hz R R2 R R1 R SR3 R SR1 RRTH1 DAC R SR4 C RT2 R RTH2 R SR2 C TH C RT1 RS1 DB1 RS2 DB2 V CC +5V C VCC RR1 R FA1 BGND 1 BGND 2 VCC C AD1 AD 1 TIP 1 HP 1 Protector BAT AGND RSN 1 /DGND U1 Le5712x C HP1 CS1 VOUT 1 RRX1 R T1 C VTX1 VTX 1 VIN 1 *R TX1 CDC 1 C DC1 CH1 R HP1 R FB1 C VRX1 BD 1 RING 1 RR1 C BD1 RS 1 R TMG1 TMG 1 D VBH BAT CD1 1 FLT 1 CD2 1 C1 1 C3 1 VBAT C2 1 C4 1 TMG 2 C3 1 C5 1 R TMG2 C BAT DET 1 VBREF IREF CAS DB 1 RD DB 1 DAC DAC DB 2 DB 2 RR2 R FA2 C VTX2 CH2 C HP2 C S2 R HP2 R FB2 BD 2 RING 2 C VRX2 R T2 HP 2 Protector RR2 VOUT 2 RRX2 C AD2 AD 2 BAT RSN 2 VTX 2 TIP 2 R REF RD C CAS C BD2 *R TX2 CDC 2 VIN 2 C DC2 DET 2 CD1 2 FLT 2 CD2 2 C1 2 C3 2 C2 2 C4 2 C3 2 C5 2 RS 2 ANALOG GROUND BATTERY GROUND DIGITAL GROUND 022503 *R TXx : See note in the parts list 18 Zarlink Semiconductor Inc. Le5712 Data Sheet APPLICATION CIRCUIT PARTS LIST (POTS WITH NO METERING) The following list defines the parts and part values required to meet target specification limits for channel i of the line card (i = 1,2). Item Quantity Type Value Tol. Rating Note Ringing and Ring Trip Sensing RRTH1 1 SMT 1 MΩ 1% 1/16 W RSR1, RSR3 2 SMT 1.82 MΩ 1% 1/16 W RSR2, RSR4 2 SMT 2 MΩ 1% 1/16 W RRTH2 1 SMT 909 kΩ 1% 1/16 W RR1, RR2 2 Resistor Hybrid 400 Ω 5% 2W CTH 1 Capacitor (X7R) 0.1 µF 20% 50 V CRT1, CRT2 2 Capacitor (X7R) 0.047 µF 20% 50 V Fault Protection and Power Supplies RFA1, RFB1, RFA2A RFB2 4 Protector 1 or 2 CS1, CS2 50 Ω Resistor Hybrid or PTC 1% Battery referenced thyristor 1 1 or 2 Capacitor (X7R) 0.1 µF 20% 100 V CBAT 1 Capacitor (X7R) 0.1 µF 20% 100 V CVCC 1 Capacitor (X7R) 0.1 µF 20% 10 V DVBH 1 MURS 120 (D0-41) DIODE RTMG1, RTMG2 2 SMT 2 3 1.8 kΩ 5% 1W 4 Other Components RREF 1 SMT 14.3 kΩ 1% 1/16 W 5 RD 1 SMT 82.5 kΩ 1% 1/16 W 6 RHP1, RHP2 2 SMT 15.0 kΩ 1% 1/16 W 7 RT1, RT2 2 SMT 100 kΩ 1% 1/16 W RRX1, RRX2 2 SMT 75.0 kΩ 1% 1/16 W CAD1, CBD1, CAD2, CBD2 4 Capacitor (X7R) 0.022 µF 20% 100 V CHP1, CHP2 2 Capacitor (X7R) 0.1 µF 20% 100 V CVTX1, CVTX2 2 Capacitor (X7R) 0.01 µF 20% 10 V CVRX1, CVRX2 2 Capacitor (X7R) 0.1 µF 20% 10 V CDC1, CDC2 2 Capacitor (X7R) 0.33 µF 20% 5V CCAS 1 Capacitor (X7R) 0.33 µF 20% 100 V RTX1, RTX2 2 SMT 2.00 kΩ 1% 1/16 W U1 1 Le5712x 8 Notes: 1. In case of single, one for each channel. In case of dual, one for one Le5712 Dual SLIC. 2. Consult protector vendor for recommended value. One for one protector device. 3. A Schottky diode with a voltage drop of 0.4V is desirable if Tip to battery fault is concerned. 4. Value was chosen to use resistor with 5% tolerance and 1 W rating. See "Thermal Management for the Le5711 and Le5712 Dual SLIC Device" for further details. 5. Sets the current limit at 33 mA. 6. Sets an off-hook detection threshold of 11 mA. 7. RHP will enhance dial pulse crosstalk performance. RHP being 15 k will make G24 from being 1/3 to 1/3.0841. RHB should be present in WinSLAC™ simulations. 8. RTX is optional and is required if CVTX is greater than 0.01µF. 19 Zarlink Semiconductor Inc. Le5712 Data Sheet PULSE METERING APPLICATION CIRCUIT (POTS WITH METERING) For use with a Quad or Octal SLAC device; earth-backed ringing. BAT R R2 R R1 R SR3 R SR1 RRTH1 DAC R SR4 C RT2 R SR2 R RTH2 C TH C RT1 RS1 DB1 RS2 DB2 RING_SOURCE 75 Vrms, 25 Hz RF1 RF2 V CC +5V R M1 C VCC RS 1 RR1 R FA1 TIP 1 BGND 1 BGND 2 C AD1 AD 1 BAT HP 1 Protector VCC VCC C M1 V M1 AGND /DGND U1 Le5712x C HP1 RSN 1 VOUT 1 R TA1 R P1 R TB1 C T1 C P1 C VRX1 R X1 C VTX1 VTX 1 VIN 1 C X1 CDC 1 C S1 R RX1 C DC1 R FB1 RING 1 CH1 R HP1 BD 1 RR1 C BD1 R FR1 RF 1 DET 1 CD1 1 FLT 1 CD2 1 TMG 1 C1 1 C3 1 VBAT C2 1 C4 1 R TMG1 D VBH BAT R TMG2 C BAT C3 1 TMG 2 VBREF C CAS C5 1 IREF C DET1 RREF RD RD CAS R M2 C M2 V M2 DB 1 DB 1 DAC DAC DB 2 RSN 2 DB 2 R P2 R TB2 C T2 RS 2 RR2 R FA2 TIP 2 CH2 HP 2 Proector C HP2 C S2 R FB2 RING 2 R HP2 BD 2 RR2 R FR2 C P2 R RX2 C VRX2 R X2 C VTX2 VTX 2 C AD2 AD 2 BAT RF 2 VOUT 2 R TA2 VIN 2 C X2 CDC 2 C DC2 DET 2 CD1 2 FLT 2 CD2 2 C1 2 C3 2 C2 2 C4 2 C3 2 C5 2 C BD2 C DET2 ANALOG GROUND BATTERY GROUND DIGITAL GROUND 022503 20 Zarlink Semiconductor Inc. Le5712 Data Sheet APPLICATION CIRCUIT PARTS LIST (POTS WITH METERING) The following list defines the parts and part values required to meet target specification limits for channel i of the line card (i = 1,2). Item Quantity Type Value Tol. Rating 1% 1/16 W Note Ringing and Ring Trip Sensing RRTH1 1 SMT 1 MΩ RSR1, RSR3 2 SMT 1.82 MΩ 1% 1/16 W RSR2, RSR4 2 SMT 2 MΩ 1% 1/16 W RRTH2 1 SMT 909 kΩ 1% 1/16 W RR1, RR2 2 Resistor Hybrid 400 Ω 5% 2W CTH 1 Capacitor (X7R) 0.1 µF 20% 50 V CRT1, CRT2 2 Capacitor (X7R) 0.047 µF 20% 50 V Fault Protection and Power Supplies RFA1, RFB1, RFA2A RFB2 4 Protector 1 or 2 CS1, CS2 50 Ω Resistor Hybrid or PTC 1% Battery referenced thyristor 1 1 or 2 Capacitor (X7R) 0.1 µF 20% 100 V CBAT 1 Capacitor (X7R) 0.1 µF 20% 100 V CVCC 1 Capacitor (X7R) 0.1 µF 20% 10 V DVBH 1 MURS 120 (D0-41) DIODE RTMG1, RTMG2 2 SMT 2 3 1.8 kΩ 5% 1W 4 Components specific to Metering application circuit CM1, CM2 2 Capacitor (X7R) 0.01 µF 20% 10 V CT1, CT2, 2 Capacitor (X7R) 1000 pF 10% 10 V CX1, CX2 2 Capacitor (X7R) 1500 pF 10% 10 V CP1, CP2 2 Capacitor (X7R) 390 pF 10% 10 V CDET1, CDET2 2 Capacitor (X7R) 0.022 µF 20% 10V RM1, RM2 2 SMT 16.5 kΩ 1% 1/16 W RTA1, RTA2, RTB1, RTB2 4 SMT 49.9 kΩ 1% 1/16 W RRX1, RRX2 2 SMT 71.5 kΩ 1% 1/16 W RP1, RP2 2 SMT 22.1 kΩ 1% 1/16 W RX1, RX2 2 SMT 4.99 kΩ 1% 1/16 W RREF 1 SMT 14.3 kΩ 1% 1/16 W 6 RD 1 SMT 82.5 kΩ 1% 1/16 W 7 RHP1, RHP2 2 SMT 15.0 kΩ 1% 1/16 W 8 CAD1, CBD1, CAD2, CBD2 4 Capacitor (X7R) 0.022 µF 20% 100 V CHP1, CHP2 2 Capacitor (X7R) 0.1 µF 20% 100 V CVTX1, CVTX2 2 Capacitor (X7R) 0.1 µF 20% 10 V CVRX1, CVRX2 2 Capacitor (X7R) 0.1 µF 20% 10 V CDC1, CDC2 2 Capacitor (X7R) 0.33 µF 20% 5V CCAS 1 Capacitor (X7R) 0.33 µF 20% 100 V U1 1 Le5712x 5 Other Components Notes: 1. In case of single, one for each channel. In case of dual, one for one Le5712 Dual SLIC. 2. Consult protector vendor for recommended value. One for one protector device. 3. A Schottky diode with a voltage drop of 0.4V is desirable if Tip to battery fault is concerned. 4. Value was chosen to use resistor with 5% tolerance and 1 W rating. See "Thermal Management for the Le5711 and Le5712 Dual SLIC Device" for further details. 5. Sets a gain of about 5.5 dB into a load of 200 Ω at tip-ring (20LOG(200/16.5/1000*500/(1+500/3.0841*(200+100)/22.1/1000)). 6. Sets the current limit at 33 mA. 7. Sets an off-hook detection threshold of 11 mA. 8. RHP will enhance dial pulse crosstalk performance. RHP being 15 k will make G24 from being 1/3 to 1/3.0841. RHB should be present in WinSLAC™ simulations. 21 Zarlink Semiconductor Inc. Le5712 Data Sheet PHYSICAL DIMENSIONS 44-Pin eTQFP Symbol A A1 A2 D D1 E E1 R2 R1 Ԧ Ԧ 1 Ԧ 2 Ԧ 3 Min 0.05 0.95 0.08 0.08 0 deg 0 deg 11 deg 11 deg Nom 1.00 12 BSC 10 BSC 12 BSC 10 BSC 3.5 deg 12 deg 12 deg Max 1.20 0.15 1.05 0.20 7 deg 13 deg 13 deg Symbol c L L1 S b e D2 E2 aaa bbb ccc ddd N Min 0.09 0.45 0.20 0.17 Nom 0.60 1.00 REF 0.20 0.80 BSC 8.00 8.00 0.20 0.20 0.10 0.20 44 Max 0.20 0.75 0.27 Notes: 1. Controlling dimension in millimeter unless otherwise specified. 2. Dimensions “D1” and “E1” do not include mold protrusion. Allowable protrusion is 0.25mm per side. “D1” and “E1” are maximum plastic body size dimensions including mold mismatch. 3. Dimension “b” does not include Dambar protrusion. Allowable Dambar protrusion shall not cause the lead width to exceed the maximum “b” dimension by more than 0.08mm. 4. Dambar can not be located on the lower radius or the foot. Minimum space between protrusion and an adjacent lead is 0.07mm for 0.4mm and 0.5mm pitch packages. 5. Square dotted line is E-Pad outline. 6. “N” is the total number of terminals. 44-Pin eTQFP Note: Packages may have mold tooling markings on the surface. These markings have no impact on the form, fit or function of the device. Markings will vary with the mold tool used in manufacturing. 22 Zarlink Semiconductor Inc. Le5712 Data Sheet REVISION HISTORY Revision C1 to D1 • • Page 9, Supply Currents and Power Dissipation, (On-hook), regarding disconnect operational state, IVBAT max from 0.7mA to 0.8mA; SLIC Device Power max from 50mW to 62mW. In Device Specifications, page 11, IGSD, Ground Start Detection Threshold, changed max from 15.2mA to 16.0mA. • In Device Specifications, page 11, IFAULT, changed max from 18mA to 20mA. • In Device Specifications, page 11, IIH, Input High Current of C1/2/3, changed max from 40µA to 90µA, min from -100µA to 110 µA, with test condition to be VIH=2.0V. • In Device Specifications, page 11, IIL, Input Low Current of C1/2/3, changed test condition to be VIL=0.8V. Revision D1 to E1 • Added green package OPNs to Ordering Information, on page 1 • Added Package Assembly, on page 8 Revision E1 to F1 • Removed Le57D123 and Le57D124 devices from Ordering Information, on page 1. Removed descriptions related to Le57D123 and Le57D124, such as old note 2 on page 12. The notes on page 12 are re-arranged that are applicable to page 9, page 10, and page 11. • • Removed non-green OPNs from Ordering Information, on page 1. Modified descriptions regarding FLTs in Pin Descriptions, on page 7. • • Updated and added note about package marking in Physical Dimensions, on page 22. Separated parts list for with and without metering applications, on page 19 and 21. Revision F1 to G1 • • Added Note 1 to Pin Descriptions, on page 7. Rearranged notes on page 12 and applicable notes in tables on pages 9, 10, and 11. • Added Application Circuit Parts List (Pots with no metering), on page 19. • Modified Application Circuit Parts List (Pots with metering), on page 21". Revision G1 to G2 • Added new headers/footers due to Zarlink purchase of Legerity on August 3, 2007 23 Zarlink Semiconductor Inc. For more information about all Zarlink products visit our Web Site at www.zarlink.com Information relating to products and services furnished herein by Zarlink Semiconductor Inc. or its subsidiaries (collectively “Zarlink”) is believed to be reliable. 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