(R) AFE AFE1105 110 5 HDSL/MDSL ANALOG FRONT END FEATURES DESCRIPTION COMPLETE ANALOG INTERFACE T1, E1, AND MDSL OPERATION Burr-Brown's Analog Front End greatly reduces the size and cost of an HDSL or MDSL system by providing all of the active analog circuitry needed to connect the Metalink MtH1210B HDSL digital signal processor to an external compromise hybrid and a 1:2.3 HDSL line transformer. All internal filter responses as well as the pulse former output scale with clock frequency--allowing the AFE1105 to operate over a range of bit rates from 196kbps to 1.168Mbps. Functionally, this unit is separated into a transmit and a receive section. The transmit section generates, filters, and buffers outgoing 2B1Q data. The receive section filters and digitizes the symbol data received on the telephone line and passes it to the MtH1210B. The HDSL Analog Interface is a monolithic device fabricated on 0.6CMOS. It operates on a single +5V supply. It is housed in a 48-pin SSOP package. CLOCK SCALEABLE SPEED SINGLE CHIP SOLUTION +5V ONLY (5V OR 3.3V DIGITAL) 250mW POWER DISSIPATION 48-PIN SSOP -40C TO +85C OPERATION Pulse Former Line Driver txLINEP txLINEN REFP PLLOUT PLLIN Voltage Reference Transmit Control txDAT VCM REFN txCLK rxSYNC Receive Control rxLOOP rxLINEP 2 rxGAIN Delta-Sigma Modulator 14 rxD13 - rxD0 rxLINEN rxHYBP rxHYBN Decimation Filter Patents Pending International Airport Industrial Park * Mailing Address: PO Box 11400, Tucson, AZ 85734 * Street Address: 6730 S. Tucson Blvd., Tucson, AZ 85706 * Tel: (520) 746-1111 * Twx: 910-952-1111 Internet: http://www.burr-brown.com/ * FAXLine: (800) 548-6133 (US/Canada Only) * Cable: BBRCORP * Telex: 066-6491 * FAX: (520) 889-1510 * Immediate Product Info: (800) 548-6132 (c) 1996 Burr-Brown Corporation SBWS003 PDS-1346 Printed in U.S.A. September, 1996 SPECIFICATIONS Typical at 25C, AVDD = +5V, DVDD = +3.3V, ftx = 584kHz (E1 rate), unless otherwise specified. AFE1105E PARAMETER RECEIVE CHANNEL Number of Inputs Input Voltage Range Common-Mode Voltage Input Impedance Input Capacitance Input Gain Matching Resolution Programmable Gain Settling Time for Gain Change Gain + Offset Error Output Data Coding Output Data Rate, rxSYNC(3) TRANSMIT CHANNEL Transmit Symbol Rate, ftx T1 Transmit -3dB Point T1 Rate Power Spectral Density(5) E1 Transmit -3dB Point E1 Rate Power Spectral Density(5) Transmit Power(5) Pulse Output Common-Mode Voltage, VCM Output Resistance(6) TRANSCEIVER PERFORMANCE Uncancelled Echo(7) DIGITAL INTERFACE(6) Logic Levels VIH VIL VOH VOL Transmit/Receive Channel Interface ttx1 ttx2 POWER Analog Power Supply Voltage Analog Power Supply Voltage Digital Power Supply Voltage Digital Power Supply Voltage Power Dissipation(4, 8) Power Dissipation(4, 8) PSRR COMMENTS MIN Differential Balanced Differential(1) 1.5V CMV Recommended All Inputs 2 Line Input vs Hybrid Input Four Gains: 0dB, 3.25dB, 6dB, and 9dB TYP MAX 3.0 +1.5 See Typical Performance Curves 10 2 14 0 9 6 Tested at Each Gain Range 5 Two's Complement DC to 1MHz 584(4) 196 See Typical Performance Curves 292 See Typical Performance Curves 13 14 See Typical Performance Curves AVDD/2 1 kHz kHz rxGAIN = 0dB, Loopback Enabled rxGAIN = 0dB, Loopback Disabled rxGAIN = 3.25dB, Loopback Disabled rxGAIN = 6dB, Loopback Disabled rxGAIN = 9dB, Loopback Disabled |IIH| < 10A |IIL| < 10A IOH = -20A IOL = 20A DVDD -1 -0.3 DVDD -0.5 txCLK Period txCLK Pulse Width 1.7 t tx1/16 Specification Operating Range Specification Operating Range DVDD = 3.3V, 1:2 Line Transformer DVDD = 5V, 1:2 Line Transformer +0.4 V V V V 10.2 15t tx1/16 s ns 5.25 V V V V mW mW dB +85 C 3.3 250 300 -40 V DVDD +0.3 +0.8 5.25 3.15 dBm dB dB dB dB dB 5 4.75 kHz -67 -67 -69 -71 -73 60 TEMPERATURE RANGE Operating(6) pF % Bits dB Symbol Periods %FSR(2) kHz 98 ETSI RTR/TM-03036 Compliant V V 584(4) 98 Bellcore TA-NWT-3017 Compliant UNITS NOTES: (1) With a balanced differential signal, the positive input is 180 out of phase with the negative input, therefore the actual voltage swing about the common mode voltage on each pin is 1.5V to achieve a differential input range of 3.0V or 6Vp-p. (2) FSR is Full-Scale Range. (3) The output data is available at twice the symbol rate with interpolated values. (4) This specification does not apply to the AFE1105EA. (5) With a pseudo-random equiprobable sequence of HDSL pulses; 13.5dBm applied to the transformer (27dBm output from txLINEP and txLINEN). (6) Guaranteed by design and characterization. (7) Uncancelled Echo is a measure of the total analog errors in the transmitter and receiver sections including the effect of non-linearity and noise. See the Discussion of Specifications section of this data sheet for more information. (8) Power dissipation includes only the power dissipated within the component and does not include power dissipated in the external loads. The AFE1105 is tested with a 1:2 line transformer, but will typically be used with a 1:2.3 line transformer, this will slightly increase power dissipation. (R) AFE1105 2 PIN DESCRIPTIONS PIN # TYPE NAME 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 Ground Power Input Ground Input Output Output Output Output Output Output Ground Power Output Output Output Output Output Output Output Output Power Input Input Input Input Power Input Input Input Input Ground Ground Output Output Output Power Ground Output Power Output Ground NC NC NC NC Output Input PGND PVDD txCLK DGND txDAT rxD0 rxD1 rxD2 rxD3 rxD4 rxD5 DGND DVDD rxD6 rxD7 rxD8 rxD9 rxD10 rxD11 rxD12 rxD13 DVDD rxSYNC rxGAIN0 rxGAIN1 rxLOOP AVDD rxHYBN rxHYBP rxLINEN rxLINEP AGND AGND REFP VCM REFN AVDD AGND txLINEN AVDD txLINEP AGND NC NC NC NC PLLOUT PLLIN DESCRIPTION Analog Ground for PLL Analog Supply (+5V) for PLL Symbol Clock (XMTLE from MtH1210B) (392kHz for T1, 584kHz for E1) Digital Ground XMTDA from MtH1210B ADC Output Bit-0 ADC Output Bit-1 ADC Output Bit-2 (RCVD0 from MtH1210B) ADC Output Bit-3 (RCVD1 from MtH1210B) ADC Output Bit-4 (RCVD2 from MtH1210B) ADC Output Bit-5 (RCVD3 from MtH1210B) Digital Ground Digital Supply (+3.3V to +5V) ADC Output Bit-6 (RCVD4 from MtH1210B) ADC Output Bit-7 (RCVD5 from MtH1210B) ADC Output Bit-8 (RCVD6 from MtH1210B) ADC Output Bit-9 (RCVD7 from MtH1210B) ADC Output Bit-10 (RCVD8 from MtH1210B) ADC Output Bit-11 (RCVD9 from MtH1210B) ADC Output Bit-12 (RCVD10 from MtH1210B) ADC Output Bit-13 (RCVD11 from MtH1210B) Digital Supply (+3.3V to +5V) ADC Sync Signal (RCVCK from MtH1210B) (392kHz for T1, 584kHz for E1) Receive Gain Control Bit-0 Receive Gain Control Bit-1 (RCVG0 from MtH1210B) Loopback Control Signal (loopback is enabled by positive signal) Analog Supply (+5V) Negative Input from Hybrid Network Positive Input from Hybrid Network Negative Line Input Positive Line Input Analog Ground Analog Ground Positive Reference Output, Nominally 3.5V Common-Mode Voltage (buffered), Nominally 2.5V Negative Reference Output, Nominally 1.5V Analog Supply (+5V) Analog Ground Transmit Line Output Negative Analog Supply (+5V) Transmit Line Output Positive Analog Ground Connection to Ground Recommended Connection to Ground Recommended Connection to Ground Recommended Connection to Ground Recommended PLL Filter Output PLL Filter Input The information provided herein is believed to be reliable; however, BURR-BROWN assumes no responsibility for inaccuracies or omissions. BURR-BROWN assumes no responsibility for the use of this information, and all use of such information shall be entirely at the user's own risk. Prices and specifications are subject to change without notice. No patent rights or licenses to any of the circuits described herein are implied or granted to any third party. BURR-BROWN does not authorize or warrant any BURR-BROWN product for use in life support devices and/or systems. (R) 3 AFE1105 PIN CONFIGURATION ABSOLUTE MAXIMUM RATINGS Top View Analog Inputs: Current .............................................. 100mA, Momentary 10mA, Continuous Voltage .................................. AGND -0.3V to AVDD +0.3V Analog Outputs Short Circuit to Ground (+25C) ..................... Continuous AVDD to AGND ........................................................................ -0.3V to 6V PVDD to PGND ........................................................................ -0.3V to 6V DVDD to DGND ........................................................................ -0.3V to 6V PLLIN or PLLOUT to PGND ......................................... -0.3V to PVDD +0.3V Digital Input Voltage to DGND .................................. -0.3V to DVDD +0.3V Digital Output Voltage to DGND ............................... -0.3V to DVDD +0.3V AGND, DGND, PGND Differential Voltage ......................................... 0.3V Junction Temperature (TJ) ............................................................ +150C Storage Temperature Range .......................................... -40C to +125C Lead Temperature (soldering, 3s) ................................................. +260C Power Dissipation ......................................................................... 700mW SSOP PGND 1 48 PLLIN PVDD 2 47 PLLOUT txCLK 3 46 NC DGND 4 45 NC txDAT 5 44 NC rxD0 6 43 NC rxD1 7 42 AGND rxD2 8 41 txLINEP rxD3 9 40 AVDD rxD4 10 39 txLINEN rxD5 11 38 AGND DGND 12 37 AVDD AFE1105E DVDD 13 36 REFN rxD6 14 35 VCM rxD7 15 34 REFP rxD8 16 33 AGND rxD9 17 32 AGND rxD10 18 31 rxLINEP rxD11 19 30 rxLINEN rxD12 20 29 rxHYBP rxD13 21 28 rxHYBN DVDD 22 27 AVDD rxSYNC 23 26 rxLOOP rxGAIN0 24 25 rxGAIN1 ELECTROSTATIC DISCHARGE SENSITIVITY This integrated circuit can be damaged by ESD. Burr-Brown recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. PACKAGE/ORDERING INFORMATION PRODUCT MAXIMUM BIT RATE AFE1105E AFE1105EA 1.168Mbps 512kbps PACKAGE PACKAGE DRAWING NUMBER(1) TEMPERATURE RANGE 48-Pin Plastic SSOP 48-Pin Plastic SSOP 333 333 -40C to +85C -40C to +85C NOTE: (1) For detailed drawing and dimension table, please see end of data sheet, or Appendix C of Burr-Brown IC Data Book. (R) AFE1105 4 TYPICAL PERFORMANCE CURVES At Output of Pulse Transformer Typical at 25C, AVDD = +5V, DVDD = +3.3V, unless otherwise specified. POWER SPECTRAL DENSITY LIMIT Power Spectral Density (dBm/Hz) -20 -38dBm/Hz for T1 -40 -80dB/decade T1 -40dBm/Hz for E1 E1 -60 -118dBm/Hz -80 196kHz 292kHz -120dBm/Hz for E1 -100 -120 1K 10K 1M 100K 10M Frequency (Hz) CURVE 1. Upper Bound of Power Spectral Density Measured at the Transformer Output. 0.4T 0.4T B = 1.07 C = 1.00 D = 0.93 QUATERNARY SYMBOLS NORMALIZED LEVEL A B C D E F G H 0.01 1.07 1.00 0.93 0.03 -0.01 -0.16 -0.05 +3 +1 -1 -3 0.0264 2.8248 2.6400 2.4552 0.0792 -0.0264 -0.4224 -0.1320 0.0088 0.9416 0.8800 0.8184 0.0264 -0.0088 -0.1408 -0.0440 -0.0088 -0.9416 -0.8800 -0.8184 -0.0264 0.0088 0.1408 0.0440 -0.0264 -2.8248 -2.6400 -2.4552 -0.0792 0.0264 0.4224 0.1320 1.25T A = 0.01 E = 0.03 F = -0.01 -1.2T -0.6T A = 0.01 H = -0.05 14T G = -0.16 0.5T F = -0.01 50T CURVE 2. Transmitted Pulse Template and Actual Performance as Measured at the Transformer Output. INPUT IMPEDANCE vs BIT RATE 200 Input Impedance (k) T1 = 784kbps, 45k E1 = 1168kbps, 30k 150 100 T1 50 E1 0 100 300 700 500 900 1100 1300 Bit Rate (kbps) CURVE 3. Input Impedance of rxLINE and rxHYB. (R) 5 AFE1105 THEORY OF OPERATION rxLOOP INPUT rxLOOP is the loopback control signal. When enabled, the rxLINEP and rxLINEN inputs are disconnected from the AFE. The rxHYBP and rxHYBN inputs remain connected. Loopback is enabled by applying a positive signal (Logic 1) to rxLOOP. The transmit channel consists of a switched-capacitor pulse forming network followed by a differential line driver. The pulse forming network receives symbol data from the XMTDA output of the MtH1210B and generates a 2B1Q output waveform. The output meets the pulse mask and power spectral density requirements defined in European Telecommunications Standards Institute document RTR/ TM-03036 for E1 mode and in sections 6.2.1 and 6.2.2.1 of Bellcore technical advisory TA-NWT-001210 for T1 mode. The differential line driver uses a composite output stage combining class B operation (for high efficiency driving large signals) with class AB operation (to minimize crossover distortion). ECHO CANCELLATION IN THE AFE The rxHYB input is designed to be subtracted from the rxLINE input for first order echo cancellation. To accomplish this, note that the rxLINE input is connected to the same polarity signal at the transformer (positive to positive and negative to negative) while the rxHYB input is connected to opposite polarity through the compromise hybrid (negative to positive and positive to negative) as shown in Figure 2. The receive channel is designed around a fourth-order delta sigma A/D converter. It includes a difference amplifier designed to be used with an external compromise hybrid for first order analog crosstalk reduction. A programmable gain amplifier with gains of 0dB to +9dB is also included. The delta sigma modulator operating at a 24X oversampling ratio produces 14 bits of resolution at output rates up to 584kHz. The basic functionality of the AFE1105 is illustrated in Figure 1 shown below. The receive channel operates by summing the two differential inputs, one from the line (rxLINE) and the other from the compromise hybrid (rxHYB). The connection of these two inputs so that the hybrid signal is subtracted from the line signal is described in the paragraph titled "Echo Cancellation in the AFE". The equivalent gain for each input in the difference amp is 1. The resulting signal then passes to a programmable gain amplifier which can be set for gains of 0dB through 9dB. The ADC converts the signal to a 14-bit digital word, rxD13-rxD0. RECEIVE DATA CODING The data from the receive channel A/D converter is coded in two's complement code. ANALOG INPUT OUTPUT CODE (rxD13 - rxD0) Positive Full Scale Mid Scale Negative Full Scale 01111111111111 00000000000000 10000000000000 RECEIVE CHANNEL PROGRAMMABLE GAIN AMPLIFIER The gain of the amplifier at the input of the Receive Channel is set by two gain control pins, rxGAIN1 and rxGAIN0. The resulting gain between 0dB and +9dB is shown below. rxGAIN1 rxGAIN0 GAIN 0 0 0dB 0 1 3.25dB 1 0 6dB 1 1 9dB txLINEP Pulse Former txDAT txLINEN Differential Line Driver rxHYBP rxHYBN 14 rxD13 - rxD0 ADC rxLINEP Programmable Gain Amp FIGURE 1. Functional Block Diagram of AFE1105. (R) AFE1105 6 rxLINEN Difference Amplifier 0.1F PLLOUT REFP VCM 0.1F 0.1F REFN 1k 0.01F 200 14.7 txLINEN 0.1F MtH1210B 1:2.3 Transformer Tip 14.7 txLINEP PLLIN 196 Ring Neg Pos 0.01F XMTDA txDAT XMTLE txCLK RCVCK rxSYNC Compromise Hybrid Neg 750 rxHYBP RCVG0 rxGAIN1 AFE1105 100pF 750 rxHYBN RCVD11 - RCVD0 rxD13 - rxD2 Pos 0.1F 2k REFN 2k 0.1F 12 DVDD rxGAIN0 Input anti-alias filter fC 1MHz rxLOOP rxLINEN PGND 750 DGND 100pF AGND AGND PVDD AVDD AVDD 5V Analog 10F 0.1F 0.1F 0.1F 4, 14, 15 NC 0.1F and 2.2F caps on 5V supplies VCXLE VCXDA CLK 0.1F AVDD 5V to 3.3V Digital VCXCK REFN 750 AGND LOG COM ANA COM 2k 2k rxLINEP AGND DVDD 0.1F 0.1F 0.1F + 1 - 10F 5 - 10 resistor for isolation RF PCM56 0.1F IOUT LE SJ DATA 18.2k 12.1k VOUT VCXCN 69.8k 5V MC33201D 30.1k 0.1F 2.2F FIGURE 2. Basic Connection Diagram. rxHYB AND rxLINE INPUT ANTI-ALIASING FILTERS The -3dB frequency of the input anti-aliasing filter for the rxLINE and rxHYB differential inputs should be about 1MHz. Suggested values for the filter are 750 for each of the two input resistors and 100pF for the capacitor. Together the two 750 resistors and the 100pF capacitor result in -3dB frequency of just over 1MHz. The 750 input resistors will result in a minimal voltage divider loss with the input impedance of the AFE1105. rxHYB AND rxLINE INPUT BIAS VOLTAGE The transmitter output on the txLINE pins is centered at midscale, 2.5V. But, the rxLINE input signal is centered at 1.5V in the circuit shown in Figure 2 above. Inside the AFE1105, the rxHYB and rxLINE signals are subtracted as described in the paragraph on echo cancellation above. This means that the rxHYB inputs need to be centered at 1.5V just as the rxLINE signal is centered at 1.5V. REFN (Pin 36) is a 1.5V voltage source. The external compromise hybrid must be designed so that the signal into the rxHYB inputs is centered at 1.5V. This circuit applies at both T1 and E1 rates. For slower rates, the antialiasing filters will give best performance with their -3dB frequency approximately equal to the bit rate. For example, a -3dB frequency of 500kHz should be used for a single pair bit rate of 500kbps. (R) 7 AFE1105 TIMING DIAGRAM Transmit Timing ttx1 ttx2 txCLK txDAT (+3 Symbol) txDAT (+1 Symbol) txDAT (-1 Symbol) txDAT (-3 Symbol) ttx1/4 ttx1/2 3ttx1/4 Receive Timing ttx1/24 min nttx1/48 ttx1/96 rxSYNC (n + 25.5) ttx1/48 (n + 1.5) ttx1/48 rxD13 - rxD0 Data 1 Data 1a 20ns Data 2 20ns 20ns 20ns NOTES: (1) Any transmit sequence not shown will result in a zero symbol. (2) All transitions are specified relative to the falling edge of txCLK. (3) Maximum allowable error for any txDAT edge is ttx1/12 (17.8ns at E1 rate; 26.6ns at T1 rate). (4) Both txDAT inputs are read by the AFE1103 at 1/8, 3/8, and 5/8 of a symbol period from the rising edge of txCLK. (5) rxSYNC can shift to one of 48 discrete delay times from the falling edge of txCLK. (6) It is recommended that rxD13 - rxD0 be read on the rising edge of rxSYNC. FIGURE 3. Timing Diagram. RECEIVE TIMING The bandwidth of the A/D converter decimation filter is equal to one half of the symbol rate. The A/D converter data output rate is 2X the symbol rate. The specifications of the AFE1105 assume that one A/D converter output is used per symbol period and the other interpolated output is ignored. The Receive Timing Diagram above suggests using the rxSYNC pulse to read the first data output in a symbol period. Either data output may be used. Both data outputs may be used for more flexible post-processing. The rxSYNC signal controls portions of the A/D converter's decimation filter and the data output timing of the A/D converter. It is generated at the symbol rate by the user and must be synchronized with txCLK. The rising edge of rxSYNC can occur at the falling edge of txCLK or it can be shifted by the user in increments of 1/48 of a symbol period to one of 47 discrete delay times after the falling edge of txCLK. (R) AFE1105 8 DISCUSSION OF SPECIFICATIONS LAYOUT The analog front end of an HDSL system has a number of conflicting requirements. It must accept and deliver digital outputs at fairly high rates of speed, phase-lock to a highspeed digital clock, and convert the line input to a highprecision (14-bit) digital output. Thus, there are really three sections of the AFE1105: the digital section, the phaselocked loop, and the analog section. UNCANCELLED ECHO The key measure of transceiver performance is uncancelled echo. This measurement is made as shown in the diagram of Figure 4. The AFE is connected to an output circuit including a typical 1:2 line transformer. The line is simulated by a 135 resistor. Symbol sequences are generated by the tester and applied both to the AFE and to the input of an adaptive filter. The output of the adaptive filter is subtracted from the AFE output to form the uncancelled echo signal. Once the filter taps have converged, the RMS value of the uncancelled echo is calculated. Since there is no far-end signal source or additive line noise, the uncancelled echo contains only noise and linearity errors generated in the transmitter and receiver. The power supply for the digital section of the AFE1105 can range from 3.3V to 5V. This supply should be decoupled to digital ground with a ceramic 0.1F capacitor placed as close to DGND (pin 12) and DVDD (pin 13) as possible. Ideally, both a digital power supply plane and a digital ground plane should run up to and underneath the digital pins of the AFE1105 (pins 3 through 26). However, DVDD may be supplied by a wide printed circuit board (PCB) trace. A digital ground plane underneath all digital pins is strongly recommended. The data sheet value for uncancelled echo is the ratio of the RMS uncancelled echo (referred to the receiver input through the receiver gain) to the nominal transmitted signal (13.5dBm into 135, or 1.74Vrms). This echo value is measured under a variety of conditions: with loopback enabled (line input disconnected); with loopback disabled under all receiver gain ranges; and with the line shorted (S1 closed in Figure 4). The phase-locked loop is powered from PVDD (pin 2) and its ground is referenced to PGND (pin 1). Note that PVDD must be in the 4.75V to 5.25V range. This portion of the AFE1105 should be decoupled with both a 10F Tantalum capacitor 13 Transmit Data txDATP 1:2 5.6 txLINEP 13 5.6 135 S1 txLINEN 576 0.047F rxHYBP 1.54k 2k 150 2k 100pF Adaptive Filter AFE1105 0.01F rxHYBN 576 0.047F 0.1F 750 rxLINEP 2k 100pF 2k rxLINEN 750 Uncancelled Echo rxD13 - rxD0 0.1F REFN FIGURE 4. Uncancelled Echo Test Diagram. (R) 9 AFE1105 and a 0.1F ceramic capacitor. The ceramic capacitor should be placed as close to the AFE1105 as possible. The placement of the Tantalum capacitor is not as critical, but should be close. In each case, the capacitor should be connected between PVDD and PGND. The remaining portion of the AFE1105 should be considered analog. All AGND pins should be connected directly to a common analog ground plane and all AVDD pins should be connected to an analog 5V power plane. Both of these planes should have a low impedance path to the power supply. In most systems, it will be natural to derive PVDD from the AVDD supply. A 5 to 10 resistor should be used to connect PVDD to the analog supply. This resistor in combination with the 10F capacitor form a lowpass filter-- keeping glitches on AVDD from affecting PVDD. Ideally, PVDD would originate from the analog supply (via the resistor) near the power connector for the printed circuit board. Likewise, PGND should connect to a large PCB trace or small ground plane which returns to the power supply connector underneath the PVDD supply path. The PGND "ground plane" should also extend underneath PLLIN and PLLOUT (pins 47 and 48). Ideally, all ground planes and traces and all power planes and traces should return to the power supply connector before being connected together (if necessary). Each ground and power pair should be routed over each other, should not overlap any portion of another pair, and the pairs should be separated by a distance of at least 0.25 inch (6mm). One exception is that the digital and analog ground planes should be connected together underneath the AFE1105 by a small trace. (R) AFE1105 10 PACKAGE OPTION ADDENDUM www.ti.com 6-Dec-2006 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty AFE1105E ACTIVE SSOP DL 48 AFE1105E/1K ACTIVE SSOP DL AFE1105E/1KG4 ACTIVE SSOP AFE1105EG4 ACTIVE SSOP 30 Lead/Ball Finish MSL Peak Temp (3) Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR 48 1000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR DL 48 1000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR DL 48 CU NIPDAU Level-2-260C-1 YEAR 30 Green (RoHS & no Sb/Br) (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. 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