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| VITESSE SEMICONDUCTOR CORPORATION Preliminary Datasheet VSC7139 Features * Four Complete Transmitter/ Receiver Functions in a Single Integrated Circuit * Full Fibre Channel (T11) and Gigabit Ethernet (IEEE 802.3z) Compliance * 1.05Gb/s to 1.36Gb/s Operation per Channel * Common or Per-Channel Transmit Byte Clocks * TTL or PECL Reference Clock Input * 1/10th or 1/20th Baud Rate Recovered Clocks Quad Transceiver for Gigabit Ethernet and Fibre Channel * Common and Per-Channel, Serial and Parallel Loopback Controls * Common Comma Detect Enable Inputs * Per-Channel Comma Detect Outputs * Cable Equalization in Receivers * Automatic Lock-to-Reference * 3.3V Power Supply, 2.67 W Max Power Dissipation * 208-Pin, 23mm BGA Packaging General Description The VSC7139 is a full-speed Quad Fibre Channel and Gigabit Ethernet Transceiver IC. Each of the four transmitters has a 10-bit wide bus, running up to 136MHz, which accepts 8B/10B encoded transmit characters and serializes the data onto high speed differential outputs at speeds up to 1.36Gb/s. The transmit data can be synchronous to the reference clock, a common transmit byte clock or a per-channel transmit byte clock. Each receiver samples serial receive data, recovers the clock and data, deserializes it into 10-bit receive characters, outputs a recovered clock and detects "Comma" characters. The VSC7139 contains on-chip (PLL) circuitry for synthesis of the baud-rate transmit clock and extraction of the clocks from the received serial streams. VSC7139 Block Diagram (1 of 4 Channels) Rx(0:9) 10 QD Serial to Q Parallel D /10 QD 0 1 Clock Recovery Rx+ Rx- RCM RCx1 RCx0 SYNCx ENCDET PLUP SLPN LPNx Tx(0:9) SEL /10/ /20 Comma Detect Loopback Control 4 0 10 DQ 4 Parallel to Serial DQ 1 Tx+ Tx- TBCx REFT REF+ REFRFCM LTCN 4 Clock Multiply Unit x10/x20 RFCO0 RFCO1 G52196-0, Rev 3.3 5/14/01 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com Page 1 VITESSE SEMICONDUCTOR CORPORATION Quad Transceiver for Gigabit Ethernet and Fibre Channel Preliminary Datasheet VSC7139 Functional Description Notation In this document, each of the four channels are identified as Channel A, B, C or D. When discussing a signal on any specific channel, the signal will have the Channel letter embedded in the name, i.e., "TA(0:9)." When referring to the common behavior of a signal which is used on each of the four channels, a lower case "x" is used in the signal name, i.e. Tx(0:9). Differential signals, i.e. RA+ and RA-, may be referred to as a single signal, i.e. RA, by dropping reference to the "+" and "-". "REF" refers to either the TTL input REFT, or the PECL differential inputs REF+/REF-, whichever is used. Clock Synthesizer The VSC7139 clock synthesizer multiplies the reference frequency provided on the REF input by 10 or 20 to achieve a baud rate clock between 1.05GHz and 1.36GHz. The REF input can be either TTL or PECL. If TTL, connect the TTL input clock to REFT. If PECL, connect the PECL inputs to REF+ and REF-. The internal clock presented to the Clock Synthesizer is a logical XNOR of REFT and REF+/-. The reference clock will be active HIGH if the unused input is HIGH. The reference clock is active LOW if the unused input is LOW. REFT has an internal pull-up resistor. Internal biasing resistors set the proper DC level on REF+/- so AC-coupling may be used. The TTL outputs, RFCO0 and RFCO1, provide a clock that is frequency locked to the REF input. This clock is derived from the clock synthesizer and is always 1/10 the baud rate, regardless of the state of the RFCM input. The on-chip PLL uses a single external 0.1F capacitor, connected between CAP0 and CAP1, to control the Loop Filter. This capacitor should be a multilayer ceramic dielectric, or better, with at least a 5V working voltage rating and a good temperature coefficient, i.e., NPO is preferred but X7R may be acceptable. These capacitors are used to minimize the impact of common mode noise on the Clock Multiplier Unit (CMU), especially power supply noise. Higher value capacitors provide better robustness in systems. NPO is preferred because if an X7R capacitor is used, the power supply noise sensitivity will vary with temperature. For best noise immunity, the designer may use a three capacitor circuit with one differential capacitor between CAP0 and CAP1, C1, a capacitor from CAP0 to ground, C2, and a capacitor from CAP1 to ground, C3. Larger values are better but 0.1F is adequate. However, if the designer cannot use a three capacitor circuit, a single differential capacitor, C1, is adequate. These components should be isolated from noisy traces. Figure 1: Loop Filter Capacitors (Best Circuit) CAP0 C2 C1 C3 VSC7139 CAP1 C1=C2=C3= >0.1F MultiLayer Ceramic Surface Mount NPO (Preferred) or X7R 5V Working Voltage Rating Page 2 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com G52196-0, Rev 3.3 5/14/01 VITESSE SEMICONDUCTOR CORPORATION Preliminary Datasheet VSC7139 Quad Transceiver for Gigabit Ethernet and Fibre Channel Serializer The VSC7139 accepts TTL input data as a parallel 10 bit character on the Tx(0:9) bus which is latched into the input register on the rising edge of either REF or TBCx. Three clocking modes are available and automatically detected by the VSC7139. If TBCC is static and RFCM is HIGH, then all four Tx(0:9) busses are latched on the rising edges of REF. If TBCC is static and RFCM is LOW, then REF is multiplied by 20 and the input busses are latched on the rising edges of REF and at the midpoint between rising edges. If TBCC is toggling but TBCB is static, then all four Tx(0:9) busses are latched on the rising edges of TBCC. If TBCB and TBCC are both toggling then the rising edge of each TBCx latches the corresponding Tx(0:9) bus. The active TBCC or TBCx inputs must be frequency-locked to REF. There is no specified phase relationship. Prior to normal data transmission, LTCN must be asserted LOW so that the VSC7139 can lock to TBCx which may result in corrupted data being transmitted. Once LTCN has been raised HIGH, the transmitters remain locked to REF and can tolerate +2 bit times of drift in TBCx relative to REF. The 10-bit parallel transmission character will be serialized and transmitted on the Tx PECL differential outputs at the baud rate with bit Tx0 (bit a) transmitted first. User data should be encoded using 8B/10B or an equivalent code. The mapping to 10B encoded bit nomenclature and transmission order is shown in Table 1, along with the recognized comma pattern. Table 1: Transmission Order and Mapping of a 10B Character Data Bit 10B Bit Position Comma Character Tx9 j x Tx8 h x Tx7 g x Tx6 f 1 Tx5 i 1 Tx4 e 1 Tx3 d 1 Tx2 c 1 Tx1 b 0 Tx0 a 0 Clock Recovery The VSC7139 accepts differential high speed serial input from the selected source (either the PECL Rx+/ Rx- pins or the internal Tx+/- data), extracts the clock and retimes the data. Equalizers are included in the receiver to open the data eye and compensate for InterSymbol Interference (ISI) which may be present in the incoming data. The serial bit stream should be encoded so as to provide DC balance and limited run length by an 8B/10B encoding scheme. The digital Clock Recovery Unit (CRU) is completely monolithic and requires no external components. For proper operation, the baud rate of the data stream to be recovered should be within +200 ppm of ten times the REF frequency. For example, Gigabit Ethernet systems would use 125MHz oscillators with a +100ppm accuracy resulting in +200 ppm between VSC7139 pairs. Deserializer The recovered serial bit stream is converted into a 10-bit parallel output character. The VSC7139 provides complementary TTL recovered clocks, RCx0 and RCx1, which are at one-twentieth of the serial baud rate (if RCM=LOW) or one-tenth (if RCM=HIGH). The clocks are generated by dividing down the high-speed recovered clock which is phase locked to the serial data. The serial data is retimed, deserialized and output on Rx(0:9). If serial input data is not present, or does not meet the required baud rate, the VSC7139 will continue to produce a recovered clock so that downstream logic may continue to function. The RCx0/RCx1 output frequency under these circumstances will differ from its expected frequency by no more than +1%. G52196-0, Rev 3.3 5/14/01 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com Page 3 VITESSE SEMICONDUCTOR CORPORATION Quad Transceiver for Gigabit Ethernet and Fibre Channel Word Alignment Preliminary Datasheet VSC7139 The VSC7139 provides 7-bit comma character recognition and data word alignment. Word synchronization is enabled on all channels by asserting ENCDET HIGH. When synchronization is enabled, the receiver examines the recovered serial data for the presence of the "Comma" pattern. This pattern is "0011111XXX", where the leading zero corresponds to the first bit received. The comma sequence is not contained in any normal 8B/ 10B coded data character or pair of adjacent characters. It occurs only within special characters, known as K28.1, K28.5 and K28.7, which are defined for synchronization purposes. Improper comma alignment is defined as any of the following conditions: 1. The comma is not aligned within the 10-bit transmission character such that Rx(0...6) = "0011111". 2. The comma straddles the boundary between two 10-bit transmission characters. 3. The comma is properly aligned but occurs in the received character presented during the rising edge of RCx0 rather than RCx1. When ENCDET is HIGH and an improperly-aligned comma is encountered, the recovered clock is stretched, never slivered, so that the comma character and recovered clocks are aligned properly to Rx(0:9). This results in proper character and word alignment. When the parallel data alignment changes in response to a improperly-aligned comma pattern, data which would have been presented on the parallel output port prior to the comma character, and possibly the comma character itself, may be lost. Possible loss of the comma character is data dependent, according to the relative change in alignment. Data subsequent to the comma character will always be output correctly and properly aligned. When ENCDET is LOW, the current alignment of the serial data is maintained indefinitely, regardless of data pattern. On encountering a comma character, SYNCx is driven HIGH. The SYNCx pulse is presented simultaneously with the comma character and has a duration equal to the data. The SYNCx signal is timed such that it can be captured by the adjoining protocol logic on the rising edge of RCx1. Functional waveforms for synchronization are given in Figure 2. The first K28.5 shows the case where the comma is detected, but it is misaligned so a change in the output data alignment is required. Note that up to three characters prior to the comma character may be corrupted by the realignment process. The second K28.5 shows the case when a comma is detected and no phase adjustment is necessary. Figure 2 illustrates the position of the SYNCx pulse in relation to the comma character on Rx(0:9). Figure 2: Misaligned and Aligned K28.5 Characters RCx0 (RCM LOW) RCx1 RCx0 (RCM HIGH) RCx1 SYNCx Rx(0:9) Data Corrupt Corrupt Corrupt K28.5 Data1 Data2 Data3 K28.5 Misaligned Comma: Stretched Aligned Comma Page 4 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com G52196-0, Rev 3.3 5/14/01 VITESSE SEMICONDUCTOR CORPORATION Preliminary Datasheet VSC7139 Quad Transceiver for Gigabit Ethernet and Fibre Channel Loopback Operation Loopback operation is controlled by the PLUP (Parallel Loopback), SLPN (Serial Loopback) and LPNx inputs as shown in Table 2. LPNx enables PLUP/SLPN on a per-channel basis when LOW. If LPNx is HIGH, PLUP/SLPN have no impact on Channel x. When SLPN and PLUP are both HIGH the transmitter output is held HIGH. When RXx is looped back to TXx, the data goes through a clock recovery unit so much of the input jitter is removed. However, the TXx outputs may not meet jitter specifications listed in the "Transmitter AC Specifications" due to low frequency jitter transfer from RXx to TXx. Table 2: Loopback Selection LPNx PLUP SLPN LOW HIGH LOW HIGH X Tranmitter Source Receiver Transmitter Transmitter HIGH Transmitter Receiver Source Receiver Receiver Transmitter Transmitter Receiver LOW LOW LOW LOW HIGH LOW LOW HIGH HIGH X JTAG Access Port A JTAG Access Port is provided to assist in board-level testing. Through this port most pins can be accessed or controlled and all TTL outputs can be tri-stated. A full description of the JTAG functions on this device is available in "VSC7139 JTAG Access Port Functionality." G52196-0, Rev 3.3 5/14/01 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com Page 5 VITESSE SEMICONDUCTOR CORPORATION Quad Transceiver for Gigabit Ethernet and Fibre Channel Preliminary Datasheet VSC7139 AC Characteristics Figure 3: Transmit Timing Waveforms REF TBCx T1 T2 Tx(0:9) 10 Bit Data Data Valid Data Valid Data Valid +/-Tx TRLAT TTLAT Tx0 Tx1 Tx2 REF TBCx Table 3: Transmitter AC Characteristics Paramete r T1 T2 TSDR,TSDF TRLAT TTLAT Description Tx(0:9) Setup time to the rising edge of TBCx or REF Tx(0:9) hold time after the rising edge of TBCx or REF Tx+/Tx- rise and fall time Latency from rising edge of REF to Tx0 appearing on TX+/TXLatency from rising edge of TBCx to Tx0 appearing on TX+/TX- Min Typ Max Units Conditions Measured between the valid data level of Tx(0:9) to the 1.4V point of TBCx or REF 1.5 1.0 -- 7bc + 0.66ns 5bc + 0.66ns -- -- -- -- -- -- -- 300 7bc + 1.46ns 11bc + 1.46ns ns ns ps 20% to 80%, 75 load to VDD/2, tested on a sample basis bc = Bit clocks ns = nanoseconds ns bc = Bit clocks ns = nanoseconds Measured at SO+/-, 1 sigma deviation of 50% crossing pointt IEEE 802.3Z Clause 38.68, tested on a sample basis Transmitter Output Jitter RJ DJ Random jitter (RMS) Serial data output deterministic jitter (pk-pk) -- -- 5 35 8 80 ps ps Page 6 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com G52196-0, Rev 3.3 5/14/01 VITESSE SEMICONDUCTOR CORPORATION Preliminary Datasheet VSC7139 Quad Transceiver for Gigabit Ethernet and Fibre Channel Figure 4: Receive Timing Waveforms RCx0 RCM=LOW RCx1 RCx0 RCM=HIGH RCx1 T1 T2 VALID VALID Rx(0:9) SYNCx VALID +/-Rx Rx0 Rx1 Rx2 RLAT RCx1 Table 4: Receive AC Characteristics Parameters T1 Description TTL Outputs Valid prior to RCx1/ RCx0 rise TTL Outputs Valid after RCx1 or RCx0 rise Delay between rising edge of RCx1 to rising edge of RCx0 Period of RCx1 and RCx0 TTL Output rise and fall time Latency from serial bit Rx0 to rising edge RCx1 Data acquisition lock time(1) Min 4.0 3.0 TBD 3.0 2.0 TBD 10 x TRX -500 1.98 x TREF -- 12bc + 2.77ns -- Typ -- -- -- -- -- -- -- -- -- -- -- Max -- -- -- -- -- -- 10 x TRX +500 2.02 x TREF 2.4 13bc + 7.28ns 1400 Units ns Conditions @ 1.0625Gb/s @ 1.25Gb/s @ 1.36Gb/s @ 1.0625Gb/s @ 1.25Gb/s @ 1.36Gb/s TRX is the bit period of the incoming data on Rx. Whether or not locked to serial data. Between VIL(max) and VIH(min), into 10 pf. load. bc = Bit clock ns = Nano second T2 T3 T4 TR, TF RLAT TLOCK ns ps ps ns bit times 8B/10B IDLE pattern. Tested on a sample basis NOTE: (1) Probability of recovery for data acquisition is 95% per Section 5.3 of FC-PH, rev. 4.3. G52196-0, Rev 3.3 5/14/01 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com Page 7 VITESSE SEMICONDUCTOR CORPORATION Quad Transceiver for Gigabit Ethernet and Fibre Channel Figure 5: REF and TBCx Waveforms Preliminary Datasheet VSC7139 TH VIH(MIN) VIL(MAX) TL REF TBCx RFCO0 RFCO1 TP Table 5: Reference Clock Requirements Parameters FR Description Frequency Range Min 105 Typ -- Max 136 Units MHz Conditions Range over which both transmit and receive reference clocks on any link may be centered Maximum frequency offset between transmit and receive reference clocks on one link FO TP DC TR/TF DC TRCR,TRCF Frequency Offset Delay from REF to RFCO0/1 RFC0/1 Duty Cycle RFC0/1 rise and fall time REF/TBCx duty cycle REF/TBCx rise and fall time -200 1.97 40 0.25 35 -- -- -- -- -- -- -- 200 3.58 60 1.5 65 1.5 ppm ns % ns % ns Between VIL(max) and VIH(min) Measured at 1.4V Between VIL(max) and VIH(min) Page 8 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com G52196-0, Rev 3.3 5/14/01 VITESSE SEMICONDUCTOR CORPORATION Preliminary Datasheet VSC7139 DC Characteristics Parameters TTL Outputs VOH VOL IOZ TTL Inputs VIH VIL IIH IIL TTL input HIGH voltage TTL input LOW voltage TTL input HIGH current TTL input LOW current 2.0 0 -- -- VDD 1.1 VDD 2.0 -- - 50 400 -- -- 50 -- TTL output HIGH voltage TTL output LOW voltage TTL output Leakage current 2.4 -- -- -- -- -- Quad Transceiver for Gigabit Ethernet and Fibre Channel Description Mi. Typ Max -- 0.5 50 Units V V A Conditions IOH = -1.0mA IOL = +1.0mA When set to high-impedance state through JTAG. 5V Tolerant Inputs VIN =2.4V VIN =0.5V 5.5 0.8 500 -500 VDD 0.7 VDD 1.5 200 -- -- V V A A PECL Input (REF+/REF-) VIH VIL IIH IIL VIN PECL input HIGH voltage PECL input LOW voltage PECL input HIGH current PECL input LOW current PECL input differential peak-topeak voltage swing TX Output differential peak-to-peak voltage swing TX Output differential peak-to-peak voltage swing PECL differential peak-to-peak input voltage swing Power supply voltage Power dissipation Supply current (All Supplies) Supply current on VDDA -- -- -- -- -- V V A A mV VIN =VIH(MAX) VIN =VIL(MIN) VIH(MIN) - VIL(MAX) High Speed Outputs VOUT75(1) VOUT50(1) 1200 1000 -- -- 2200 2200 mVp-p mVp-p 75 to VDD - 2.0 V (TX+) - (TX-) 50 to VDD - 2.0 V (TX+) - (TX-) High Speed Inputs VIN(1) Miscellaneous VDD PD IDD IDDA 3.14 -- -- -- -- 2.2 -- 100 3.47 2.67 770 -- V W mA mA 3.3V + 5% Max at 3.47V, outputs open, 136MHz Clk, PRBS 2-7, parallel input pattern, at +25C. 200 -- 2600 mV Rx+ - Rx- NOTE: (1) Refer to Application Note, AN-37, for differential measurement techniques. G52196-0, Rev 3.3 5/14/01 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com Page 9 VITESSE SEMICONDUCTOR CORPORATION Quad Transceiver for Gigabit Ethernet and Fibre Channel Preliminary Datasheet VSC7139 Absolute Maximum Ratings (1) Power Supply Voltage (VDD) .............................................................................................................-0.5V to +4V DC Input Voltage (PECL inputs)............................................................................................ -0.5V to VDD +0.5V DC Input Voltage (TTL inputs) ......................................................................................................... -0.5V to 5.5V DC Output Voltage (TTL outputs) ........................................................................................ -0.5V to VDD + 0.5V Output Current (TTL outputs) .................................................................................................................. +/-50mA Output Current (PECL outputs).................................................................................................................+/-50mA Case Temperature Under Bias .........................................................................................................-55o to +125oC Storage Temperature..................................................................................................................... -65oC to +150oC NOTE: (1) CAUTION: Stresses listed under "Absolute Maximum Ratings" may be applied to devices one at a time without causing permanent damage. Functionality at or above the values listed is not implied. Exposure to these values for extended periods may affect device reliability. Recommended Operating Conditions Power Supply Voltage (VDD) .................................................................................................................+3.3V+5% Operating Temperature Range ........................................................... 0oC Ambient to +100oC Case Temperature Page 10 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com G52196-0, Rev 3.3 5/14/01 VSC7139 Preliminary Datasheet G52196-0, Rev 3.3 5/14/01 1 VSST SYNCB RCB0 RB0 RB4 RB6 VDDT VDD VSST RC1 VDDT RC8 VSST VDDT VSST 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 Table 6: Pin Table A RA9 VSST RCB1 RB1 VDDT RB7 VSS SYNCC RC0 RC2 RC5 RC9 SYNCD RCD0 RCD1 VSST VDD B RA6 VDDT VDDT RB2 VSST RB8 SLPN RCC0 VDDT RC3 RC6 VDD VDDT VSST RD0 RA7 RA8 C VDDT VSST LPND RB3 RB5 RB9 TMS RCC1 VSST RC4 RC7 RD1 RD2 RD3 RA4 RA5 D RA2 RA3 VDDT VSST RD5 RA0 RA1 RD4 E VDDT VSST RD7 RD8 RCA0 RCA1 RD6 F VSS VDD TC2 TBCB SYNCA RD9 VSS G TB6 TB7 TC6 TB8 TB9 TC1 TC0 VDDT H TB2 TB3 TB4 TB5 TC5 TC4 TC3 J VSS LPNC TB0 TB1 NOT POPULATED VDD TC9 TC8 TC7 K VSS VDD TBCA TDO VSS VSS VDD TBCC L TA6 TA7 TA8 TA9 TD3 TD2 TD1 TD0 VITESSE SEMICONDUCTOR CORPORATION M TA2 TA3 TA4 TA5 TD7 TD6 TD5 TD4 N REFTAVSS TBVSS LPNB CAP0 TA0 TA1 PLUP VDD TD9 TD8 P LPNA TA+ VSS TB+ VDD VSSA LTCN RFCM VSS TC+ VSS TD+ RFCO1 TDI RFCO0 TBCD (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com CAP1 VSS TCVSS TDVDD TRSTN VDDTR ENCDET VDD VDD VDDPA VSS VDDPB VSS VDDA VSS VDDPC VSS VDDPD VDD VSS VSSTR TCK RARA+ VDD RBRB+ VSS VSS RCRC+ VSS RDRD+ VSS VSS VSS R REFT REF+ T RCM VSS Quad Transceiver for Gigabit Ethernet and Fibre Channel U VSS VSS Page 11 VITESSE SEMICONDUCTOR CORPORATION Quad Transceiver for Gigabit Ethernet and Fibre Channel Table 7: Pin Identifications Pin N1, N2, N3 N4, M1, M2, M3, M4, L1 L2 J1, J2, J3 J4, H1, H2 H3, H4, G1 G2 G16, G15, G14 H17, H16, H15 H14, J17, J16 J15 L17, L16, L15 L14, M17, M16 M15, M14, N17 N16 Preliminary Datasheet VSC7139 Description Name TA0, TA1, TA2 TA3, TA4, TA5 TA6, TA7, TA8 TA9 TB0, TB1, TB2 TB3, TB4, TB5 TB6, TB7, TB8 TB9 TC0, TC1, TC2 TC3, TC4, TC5 TC6, TC7, TC8 TC9 TD0, TD1, TD2 TD3, TD4, TD5 TD6, TD7, TD8 TD9 INPUT - TTL: 10-bit Transmit bus for Channel A. Parallel data on this bus is latched on the rising edge of REF, TBCC or TBCA. TA0 is transmitted first. INPUT - TTL: 10-bit Transmit bus for Channel B. Parallel data on this bus is latched on the rising edge of REF, TBCC or TBCB. TB0 is transmitted first. INPUT - TTL: 10-bit Transmit bus for Channel C. Parallel data on this bus is latched on the rising edge of REF or TBCC. TC0 is transmitted first. INPUT - TTL: 10-bit Transmit bus for Channel D. Parallel data on this bus is latched on the rising edge of REF, TBCC or TBCD. TD0 is transmitted first. INPUT - Differential PECL or TTL: This rising edge of REF+/- provides the reference clock, at 1/10th or 1/20th of the baud rate (depending on RFCM) to the Clock Multiplying PLL. If REF+/- is used, either leave REFT open or set REFT HIGH. Internally biased to VDD/2. If all TBCx inputs are HIGH, the rising edge of REF will latch Tx(0:9) on all four channels INPUT - TTL: TTL REFerence clock. This rising edge of REFT provides the reference clock, at 1/10th or 1/20th of the baud rate (depending on RFCM) to the Clock Multiplying PLL. If REFT is used, set REF+ HIGH and leave REF- open. If all TBCx inputs are HIGH, the rising edge of REFT will latch Tx(0:9) on all four channels INPUT - TTL: REFerence clock Mode select. When LOW, REF is at 1/20th of the transmit baud rate (i.e. 62.5 MHz for 1.25 Gb/s). When HIGH, REF is at 1/10th the baud rate (i.e. 125 MHz for 1.25 Gb/s). OUTPUT - TTL: These are identical copies of the transmit baud rate clock divided by 10. INPUT - TTL: Per channel Transmit Byte Clock for Channel x. All four channels' parallel Tx(0:9) inputs may be timed to REF, TBCC, or independently to TBCx. Refer to the Serializer description. INPUT - TTL: Latch Transmit Byte Clocks. When LOW, internal PLLs align clocks with each of the transmit byte clocks, if present. Data may be corrupted when LOW. When HIGH, alignment will remain static regardless of actual TBCx location. R2 P3 REF+ REF- R1 REFT P2 P16 P14 K1, F1 K17, P17 RFCM RFCO0 RFCO1 TBCA, TBCB TBCC, TBCD P1 LTCN Page 12 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com G52196-0, Rev 3.3 5/14/01 VITESSE SEMICONDUCTOR CORPORATION Preliminary Datasheet VSC7139 Pin R5, P5 R7, P7 P11, R11 P13, R13 D1, D2, E3 E4, C1, C2 C3, B1, B2 B3 A6, B6, C6 D6, A7, D7 A8, B8, C8 D8 B11, A12, B12 C12, D12, B13 C13, D13, A14 B14 C17, D14, D15 D16, D17, E16 E17, F14, F15 F16 T1 E1 E2 A5 B5 C10 D10 B16 B17 U4, U3 U7, U6 U11, U10 U14, U13 N14 Quad Transceiver for Gigabit Ethernet and Fibre Channel Description OUTPUT - Differential PECL (AC Coupling recommended) These pins output the serialized transmit data for Channel x when PLUP is LOW. When PLUP is HIGH, Tx+ is HIGH and Tx- is LOW. Name TA+, TATB+, TBTC+, TCTD+, TDRA0, RA1, RA2 RA3, RA4, RA5 RA6, RA7, RA8 RA9 RB0, RB1, RB2 RB3, RB4, RB5 RB6, RB7, RB8 RB9 RC0, RC1, RC2 RC3, RC4, RC5 RC6, RC7, RC8 RC9 RD0, RD1, RD2 RD3, RD4, RD5 RD6, RD7, RD8 RD9 RCM RCA0 RCA1 RCB0 RCB1 RCC0 RCC1 RCD0 RCD1 RA+, RARB+, RBRC+, RCRD+, RDPLUP OUTPUT - TTL: 10-bit Receive bus for Channel A. Parallel data on this bus is synchronous to RCA0 and RCA1. RA0 is the first bit received. OUTPUT - TTL: 10-bit Receive bus for Channel B. Parallel data on this bus is synchronous to RCB0 and RCB1. RB0 is the first bit received. OUTPUT - TTL: 10-bit Receive bus for Channel C. Parallel data on this bus is synchronous to RCC0 and RCC1. RC0 is the first bit received. OUTPUT - TTL: 10-bit Receive bus for Channel D. Parallel data on this bus is synchronous to RCD0 and RCD1. RD0 is the first bit received. INPUT - TTL: Recovered clock MODE control. When LOW, RCx0/RCx1 is 1/20th of the incoming baud rate. When HIGH, RCx0/RCx1 is 1/10th the incoming baud rate. OUTPUT - Complementary TTL: Recovered complementary clocks for Channel A at 1/ 10th the incoming baud rate (RCM=HIGH) or 1/20th (RCM=LOW). Synchronous to the RA(0:9) and SYNCA bus. OUTPUT - Complementary TTL: Recovered complementary clocks for Channel B at 1/ 10th the incoming baud rate (RCM=HIGH) or 1/20th (RCM=LOW). Synchronous to the RB(0:9) and SYNCB bus. OUTPUT - Complementary TTL: Recovered complementary clocks for Channel C at 1/ 10th the incoming baud rate (RCM=HIGH) or 1/20th (RCM=LOW). Synchronous to the RC(0:9) and SYNCC bus. OUTPUT - Complementary TTL: Recovered complementary clocks for Channel D at 1/ 10th the incoming baud rate (RCM=HIGH) or 1/20th (RCM=LOW). Synchronous to the RD(0:9) and SYNCD bus. INPUT - Differential PECL (AC Coupling recommended): Serial receive data inputs for Channel x which are selected when PLUP is LOW. [Internally biased to VDD/2] INPUT - TTL: Parallel Loopback Enable input. Rx is input to the CRU for Channel x (normal operation) when PLUP is LOW. When HIGH, internal loopback paths from Tx to Rx are enabled. Refer to Table 2. G52196-0, Rev 3.3 5/14/01 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com Page 13 VITESSE SEMICONDUCTOR CORPORATION Quad Transceiver for Gigabit Ethernet and Fibre Channel Pin C9 R3 P4 K4 D5 R17 F2 A4 B10 B15 P9 R9 T17 D9 R15 P15 K2 T9 R8 A2,A10,C14 G4,J14,K16 L4,N15,R4 R14,T3 T4,T14,U5 C4, D3,F3 A9, B7, C5 A13, A16, C11 C15, E14, G17 T5 T7 T11 T13 R16 T16 A1,A3,A11,A15 A17,B4,C7 C16,D4,D11 E15,F4 Preliminary Datasheet VSC7139 Description Name SLPN LPNA LPNB LPNC LPND ENCDET SYNCA SYNCB SYNCC SYNCD CAP0 CAP1 TCK TMS TRSTN TDI TDO VDDA VSSA INPUT - TTL: Serial Loopback enable input. Normal operation when HIGH. When LOW, Rx+/- is looped back to Tx+/- internally for diagnostic purposes. Refer to Table 2 and related description. INPUT - TTL: Loopback Enable Pins. When LPNx is LOW, PLUP/SLPN impact Channel x. When HIGH, PLUP/SLPN have no effect on Channel x. INPUT - TTL: Enables SYNCx and word alignment when HIGH. When LOW, keeps current word alignment and disables SYNCx (always LOW). OUTPUT - TTL: Comma Detect for Channel x. This output goes HIGH for half of an RCx1 period to indicate that Rx(0:9) contains a Comma Character (`0011111XXX'). SYNCx will go HIGH only during a cycle when RCX0 is rising. SYNCx is enabled when ENCDET is HIGH. ANALOG: Loop Filter capacitor for the Clock Multiply Unit. Typically 0.1 uF connected between CAP0 and CAP1. Amplitude is less than 3.3V. INPUT - TTL: JTAG Test Clock INPUT - TTL: JTAG Test Mode Select INPUT - TTL: JTAG Test Reset, Active Low INPUT - TTL: JTAG Test Data Input OUTPUT - TTL: JTAG Test Data Output Analog Power Supply Analog Ground. Tie to common ground plane with VSS. VDD Digital Logic Power Supply VDDT TTL Output Power Supply. VDDPA VDDPB VDDPC VDDPD VDDTR VSSTR PECL I/O Power Supply for Channel x. TTL Output Power Supply for RFCO0 and RFCO1 TTL Ground for RFCO0 and RFCO1 VSST Ground for TTL Outputs Page 14 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com G52196-0, Rev 3.3 5/14/01 VITESSE SEMICONDUCTOR CORPORATION Preliminary Datasheet VSC7139 Pin B9,F17,G3,K3, K14,K15,L3,P6, P8,P10,P12 R6,R10,R12,T2T 6,T8,T10,T12T1 5,U1,U2,U8,U9, U12,U15 U16, U17 Quad Transceiver for Gigabit Ethernet and Fibre Channel Description Name VSS Ground Package Thermal Characteristics The VSC7139 is packaged in a 23 mm BGA package with 1.27mm eutectic ball spacing. The construction of the package is shown in Figure 6. Figure 6: Package Cross Section Copper Heat Spreader Die Attach Epoxy Adhesive Die Wirebond Polyimide Dielectric Encapsulant Eutectic Solder Balls The VSC7139 is designed to operate with a case temperature up to 100oC. In order to comply with this target, the user must guarantee that the case temperature specification of 100oC is not violated. With the Thermal Resistances shown in Table 8, the VSC7139 can operate in still air ambient temperatures of 56.75oC [ 56.75oC = 100oC - 2.5W * 17.3oC/W ]. If the ambient air temperature exceeds these limits then some form of cooling through a heatsink or an increase in airflow must be provided. Table 8: Thermal Resistance Symbol jc ca ca-100 ca-200 ca-400 ca-600 Description Thermal resistance from junction to case Thermal resistance from case to ambient in still air including conduction through the leads. Thermal resistance from case to ambient with 100 LFM airflow Thermal resistance from case to ambient with200 LFM airflow Thermal resistance from case to ambient with 400 LFM airflow Thermal resistance from case to ambient with 600 LFM airflow Value 1.0 17.3 15.7 14.5 13.0 12.0 Units o o o o o o C/W C/W C/W C/W C/W C/W Moisture Sensitivity Level This device is rated at a Moisture Sensitivity Level 3 rating with maximum floor life of 168 hours at 30C, 60% relative humidity. Please refer to Application Note AN-20 for appropriate handling procedures. G52196-0, Rev 3.3 5/14/01 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com Page 15 VITESSE SEMICONDUCTOR CORPORATION Quad Transceiver for Gigabit Ethernet and Fibre Channel Preliminary Datasheet VSC7139 Package Information Pin A1 Indicator 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 A B C D E F G H J K L M N P R T U 23.0 1.27 Typ BOTTOM VIEW 23.0 TOP VIEW 1.55 Typ Page 16 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com G52196-0, Rev 3.3 5/14/01 VITESSE SEMICONDUCTOR CORPORATION Preliminary Datasheet VSC7139 Order information Quad Transceiver for Gigabit Ethernet and Fibre Channel The order number for this product is formed by a combination of the device number, and package type. VSC7139 Device Type Quad Gigabit Transceiver Package TW: 208-Pin, 23mm BGA XX Marking Information The top of the package is marked as in Figure 7. Figure 7: Package Marking Information Pin 1 Identifier Part Number DateCode VSC7139TW ####AAAA VITESSE Package Suffix Lot Tracking Code (4 or 5 characters) Notice Vitesse Semiconductor Corporation ("Vitesse") provides this document for informational purposes only. This document contains pre-production information about Vitesse products in their concept, development and/or testing phase. All information in this document, including descriptions of features, functions, performance, technical specifications and availability, is subject to change without notice at any time. Nothing contained in this document shall be construed as extending any warranty or promise, express or implied, that any Vitesse product will be available as described or will be suitable for or will accomplish any particular task. Vitesse products are not intended for use in life support appliances, devices or systems. Use of a Vitesse product in such applications without written consent is prohibited. G52196-0, Rev 3.3 5/14/01 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com Page 17 VITESSE SEMICONDUCTOR CORPORATION Quad Transceiver for Gigabit Ethernet and Fibre Channel Preliminary Datasheet VSC7139 This page left intentionally blank. Page 18 (c) VITESSE SEMICONDUCTOR CORPORATION * 741 Calle Plano * Camarillo, CA 93012 Tel: (800) VITESSE * FAX: (805) 987-5896 * Email: prodinfo@vitesse.com Internet: www.vitesse.com G52196-0, Rev 3.3 5/14/01 |
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