AN1672/D The ECL Translator Guide PECL • LVPECL • NECL • TTL • LVTTL/LVCMOS • CMOS http://onsemi.com Prepared by: Paul Shockman ON Semiconductor APPLICATION NOTE Objective receiver) in the LOW state. In contrast, ECL drivers source current in both HIGH and LOW states (to the receiver). Receiver inputs do not require any “termination” although any driver may or may not require termination considerations. The driver termination considerations may be located physically near or internal to a receiver. TTL and CMOS devices will usually be operated across a single positive power supply (VCC or VDD) and ground. ECL devices may operate similarly across a single Positive supply and VEE (Ground) as Positive ECL (PECL) or Low Voltage Positive ECL (LVPECL). Or traditionally, ECL devices may span across Ground and a single negative power supply, VEE, as Negative ECL (NECL) or Low Voltage Negative ECL (LVNECL). Any device may be operated with all pins offset by a fixed voltage, but interface with standard levels may require a translation device. A pure ECL device might be operated in NECL, PECL, or LVPECL mode by simply shifting all voltage levels. Of course, a translator dedicated to a specific technology will expect only fixed voltages and can’t usually operate in different, or shifted voltage modes. The NB4N, NB7L, and NBSG series logic family devices are capable of direct translation of CML, RSECL, LVPECL, LVDS, LVCMOS, and LVTTL. The specific device data sheet should be consulted for input capabilities. This application note is intended to provide the basic device selection and connection information to enable signal translation interface between ON Semiconductor’s ECL logic operating in various supply modes This document also provides information regarding translation between our ECL devices and TTL (5 V), CMOS (5 V), or LVTTL/LVCMOS (3.3 V) devices. For translation interface with LVDS, see AN1568. Translation to and from ECL technology is discussed in three section divisions: Section 1. Translation between differently supplied ECL drivers and receivers Section 2. Translation from different ECL operating mode drivers to non ECL receivers Section 3. Translation from non ECL drivers to different ECL operating mode receivers Proper translation occurs when the driver’s output logic levels are within the spec limits of the receiver and are recognized. Specific device data sheets should be consulted for exact specifications and parameter limits. Resources IBIS and SPICE models may be found at www.onsemi.com for most devices. General ECL information, also online, may be consulted such as AND8020, AND8066, and AND8072. General Background TTL and CMOS drivers generally source current (to the receiver) in the HIGH state and sink current (from the © Semiconductor Components Industries, LLC, 2006 March, 2006 − Rev. 12 1 Publication Order Number: AN1672/D AN1672/D Different ECL operating supply modes are generally considered to be as presented below in Table 1. These are nominal values and range according to the specific device data sheet. VCC ripple should be minimized and may require additional filter networks. Standard non ECL operating modes are generally considered (with certain supply tolerances) to be as presented below in Table 2. Table 1. ECL Operating Supply Modes PECL VCC = 5.0, VEE = 0.0 LVPECL VCC = 3.3, VEE = 0.0 2.5VPECL VCC = 2.5, VEE = 0.0 2.5VNECL VCC = 0.0, VEE = −2.5 LVNECL VCC = 0.0, VEE = −3.3 NECL VCC = 0.0, VEE = −5.0 Table 2. Non ECL Operating Supply Modes VCC = 5.0, VEE = 0.0 VCC = 3.3, VEE = 0.0 VCC = 2.5, VEE = 0.0 Most translation interface between technologies will require a separate, dedicated translator IC device, but some newer ECL devices offer a translation feature integrated into certain mode control pins. Several of the GigaComm™ devices offer a programmable mode pins for selecting the control pins translation levels. MC10EP195 offers Delay Select pins with user programmable TTL, CMOS, or ECL threshold levels. An alternative translation technique, cap coupling, is discussed in Application Note AND8020, Section 5. Cap coupling may accommodate level shifting when the signal’s “edge density” is sufficient. Otherwise, coding may be required to increase ”edge density”. Certainly the risk of erroneous levels, due to the coupling cap leakage, may not be acceptable and system requirements may demand the hard levels found with active device translation. Some devices may span one or more operating modes and each mode will allow supply tolerances. ECL signal levels (VOL, VOH, VIL, and VIH) are referenced from the VCC pin or positive rail. Therefore, when ECL devices are operated from different negative power supplies, no translation is required for interconnects. When operated in a single ended configuration, the critical Input parameters are VIL and VIH limits (VIHCMR and Vpp are ignored). When operation differentially, critical limit Input parameters are VIHCMR and Vpp (VIL and VIH are ignored). See AND8066 for interconnect details. All supply pins, VCC, LVCC, and GND, must be connected for proper operation. A 0.1 mF to 0.01 mF decoupling cap is recommended from VCC to GND. http://onsemi.com 2 AN1672/D Section 1: Translation Between Differently Supplied ECL Drivers and Receivers Table 3. Translation Between Differently Supplied ECL Drivers and Receivers To: PECL VCC = +5 V LVPECL VCC = +3.3 V LVNECL VEE = −3.3 V NECL VEE = −4.5 to −5.2 V Standard Connection MC100LVEL92 MC100LVEL92 + MC100LVEL91 or NB100LVEP91 MC100EL91 LVPECL VCC = +3.3 V MC100EL17 MC10EP17 MC100EP17 MC100LVEL16 MC100LVEL17 Direct Connection MC100LVEL91 NB100LVEP91 NB100LVEP91 LVNECL VEE = −3.3 V MC100EL90 MC100LVEL90 Standard Connection Direct Connection NECL VEE = −4.5 V to −5.2 V MC100EL90 MC100LVEL90 Standard Connection Standard Connection From: PECL VCC = +5 V From PECL to LVPECL recognize the drivers HIGH level 2.155 V (or higher). The MC100EL13, MC100EL14, MC100EL29, MC100EL56 are also acceptable as LVPECL receivers differentially. Most of the “E” (ECLinPS), “EL” (ECLinPS Lite), 10H/100H, or 10xxx series devices do not have a sufficiently low VIHCMRmin to receive LVPECL. When a receiver in LVPECL mode is driven single ended, the critical parameters will be VIL and VIH. VIHCMRmin (or VCMRmin) may be ignored. A PECL receiver VILmin, typically >3.0 V, will be insufficiently low to recognize the drivers HIGH level and will not permit proper interconnect. The MC100LVEL92 translates signals from a PECL (VCC = 5.0, VEE = 0.0) operating mode driver to a LVPECL VCC = 3.3, VEE = 0.0 operating mode receiver. From PECL to NECL The MC100EL91 translates signals from a PECL operating mode driver (supplied by VCC = 5.0, VEE = 0.0) to a NECL operating mode receiver (supplied by VCC = 0.0, VEE = −5.0 nom). From PECL to LVNECL This translation requires two devices for a direct, active connection. First, a level shift from PECL to LVPECL is done with the MC100LVEL92 and requires two positive supplies, one at 5.0 V and one at 3.3 V. Then, a translation from LVPECL to LVNECL is done with either the NB100LVEP91 or the MC100LVEL91. From LVPECL to LVNECL The MC100LVEL91 or NB100LVEP91 translates signals from a LVPECL (VCC = 3.3, VEE = 0.0) operating mode driver to a LVNECL (VCC = 0.0, VEE = −3.3) operating mode receiver. From LVPECL to NECL From LVPECL to PECL The NB100LVEP91 or MC100LVEL91 translates signals from a LVPECL (VCC = 3.3, VEE = 0.0) operating mode driver to a NECL (VCC = 0.0, VEE = −5.0) operating mode receiver. The critical parameter for differential PECL receiver to properly interface with a differential LVPECL driver is VIHCMRmin (or VCMRmin). VIH and VIL limits may be disregarded for differential receiving. Assuming no tangent loss from traces, if the LVPECL driver VOHmin level is more positive (higher) than the VIHCMRmin spec of the differential PECL receiver, the device will properly translate or level shift from LVPECL to PECL. For example, suppose a MC100EP16 operating differentially in LVPECL mode (VCC = 3.3, VEE = 0.0) with a worst case VOHmin of 2.155 V, drives a MC100EP17 receiver differentially operating in PECL mode (VCC = 5.0, VEE = 0.0). The MC100EP17 receiver spec VIHCMRmin is 2.0 V and will always properly From LVNECL to PECL The MC100EL90 translates signals from a LVNECL (VCC = 0.0, VEE = −3.3) operating mode driver to a PECL (VCC = 5.0, VEE = 0.0) operating mode receiver. From LVNECL to LVPECL The MC100LVEL90 translates signals from a LVNECL (VCC = 0.0, VEE = −3.3) operating mode driver to a PECL (VCC = 3.3, VEE = 0.0) operating mode receiver. http://onsemi.com 3 AN1672/D Section 2: Translation from Different ECL Operating Mode Drivers to Non ECL Receivers The following table indicates the options available for translation from different ECL operating drivers to non ECL receivers. Table 4. Translation from Different ECL Operating Mode Drivers to Non ECL Receivers TTL VCC = +5 V LVTTL/LVCMOS VCC = 3.3 V CMOS VDD = 5 V PECL VCC = +5 V MC10H350 MC10H607 MC100H607 MC10ELT21 MC100ELT21 MC100ELT23 MC10ELT28 MC100ELT28* MC100LVEL92 + MC100LVELT23 or MC10EPT21 MC100EPT21 or MC10EPT23 MC100EPT23 or MC100LVELT23 or MC10EPT26 MC100EPT26 PECL to TTL or PECL to LVTTL/LVCMOS Translator and HCT or ACT LVPECL VCC = +3.3 V MC10ELT21 MC100ELT21 MC100ELT23 MC10EPT21 MC100EPT21 MC10EPT23 MC100EPT23 MC100LVELT23 MC10EPT26 MC100EPT26 LVPECL to LVTTL Translator and HCT or ACT Input LVNECL VEE = −3.3 V MC10ELT25 MC100ELT25 MC10EPT25 MC100EPT25* MC10EPT25 MC100EPT25 LVNECL/TTL Translator to HCT or ACT Input NECL VEE = −4.5 to −5.2 V MC10H125 MC10H601 MC100H601 MC10H603 MC100H603 MC10H605 MC100H605 MC10H680 MC100H680* MC10H681 MC100H681* MC10ELT25 MC100ELT25 MC10EPT25 MC100EPT25* MC10EPT25 MC100EPT25 NECL/TTL Translator to HCT or ACT Input From: To: *See text segment for details From PECL to TTL 50 pF and 500 W to GND. MR, Pin 19, will default LOW when floating open, allowing operation. The input pin “common mode” range is insufficient to allow recognition of LVPECL levels. ELT21/23/28 as PECL to TTL ECL inputs for ELT21/23/28 have 50 kW internal pulldown resistors. If both ECL ELT21/23 inputs are pulled below 1.3 V, an override circuit will force the output Q to HIGH, Qb LOW. By adding an output pullup resistor of 1 to 4 kW, a device will interface with CMOS (5 V) inputs. The input common mode range for ELT21 / ELT23 is generally considered to be sufficient (2.2 V) to allow recognition of PECL HIGH levels (>4 V) allowing translation. Single ended operation may be accomplished with a VBB reference voltage placed on the nondriven differential input. If a VBB pin is present, then it should be bypassed when used or left floating open when unused. A simple VBB supply may be created by a resistor divider providing the proper switch point voltage to preserve duty cycle (see AND8066). A High Current may be created from a simple buffer gate as shown in AND8020, Figure 22. These ELT TTL devices typically display >2X the required data sheet drive. For example, at VOLmax (0.5 V) the required sinking drive current is 24 mA and actual drive >>50 mA. At VOHmin (2.4 V), the spec sourcing drive current is 3.0 mA and the typical device will source >>8 mA. The unloaded VOH max may reach as positive as 4.0 V. MC10H350 as PECL to TTL Several devices are offered for translation signals from PECL mode drivers to 5 V supplied TTL receivers. The MC10H350 operates over the frequency range from DC to about 50 MHz. Although operation is possible to 80 MHz, the output will not sustain full spec VOH levels rolling off with higher frequency. Open, floating differential inputs on a gate will force the TTL output to default LOW. By adding a pullup resistor of 1 kW to 4 kW, a device’s output will directly interface with CMOS (5 V) inputs. The device input pin “common mode range”, VIHCMR min to max, is insufficient to allow recognition of LVPECL levels. Single ended operation of the MC10H350 will require an input signal swing of 700 mV peak−to−peak or greater. Outputs are Enabled by Pin 9, OE, going LOW. If left floating open, MC10H350 Pin 9 will default LOW. Worst case skew from Output to Output within a device occurs from Input falling edge to Output falling edge at 125°C at 1.4 ns. For the Input rising edge to Output rising edge, the worst case skew is about 1 ns (at −55°C). Device to Device slew is less than 800 ps skew from part to part. Output drive will come out of saturation with 80 mA − 100 mA, lowering VOH levels. MC10H607 / MC100H607 as PECL to TTL The MC10H607 and MC100H607 are Registered PECL to TTL translators. A standard output test condition load is http://onsemi.com 4 AN1672/D Typical drive current strength of the TTL output is shown in the following two tables, Table 5 and Table 6, and their graphs, Figure 1 and Figure 2. 120 Table 5. ELT TTL Series Drive LOW Current (IOL) vs Voltage (VOL) VOL (V) 10 0.162 20 0.209 30 0.256 40 0.303 79 0.465 118 0.628 100 80 IOL (mA) IOL (mA) 60 40 20 0 0 0.1 0.2 0.3 0.4 VOL (V) 0.5 0.6 0.7 Figure 1. ELT TTL Series Drive LOW Current (IOL) versus Voltage (VOL) −40 Table 6. ELT Series TTL Drive HIGH Current (IOH) vs Voltage (VOH) VOH (V) −37.9 2 −31.6 2.26 −24.9 2.508 −16.4 2.9 −9.1 3.167 −3.1 3.339 −1.0 3.4 −30 IOH (mA) IOH (mA) −20 −10 0 2 2.5 3 3.5 VOH (V) Figure 2. ELT Series TTL Drive HIGH Current (IOH) versus Voltage (VOL) From PECL to CMOS Typical ELT TTL series output impedance in the HIGH state is about 43 W. In the LOW state output impedance is about 42 W. Typical tPLH and tPHL may differ as much as 0.5 ns. At higher frequencies, the output swing will decrease. Gain is typically about five and inputs require a minimum of 200 mVpp swing. Jitter is typically 500 ps. Measurements are made at 1.5 V for AC characteristics such as tpd and skew. The translation from PECL to CMOS is accomplished through two stages, from PECL to an intermediary stage (such as either TTL or LVTTL), then from the intermediary stage to CMOS. When the intermediary stage is through TTL, then the final stage will be from TTL to CMOS using any of the HCT type devices (i.e., MC74HCT245A), or ACT (i.e., MC74ACT244). From LVPECL to TTL Translation from LVPECL to TTL will be similar to “PECL to LVTTL” and the prior segment should be reviewed. The input common mode range maximum (2.2 V) for ELT21 / ELT23 is generally considered to be sufficient to allow recognition of LVPECL HIGH levels (>2.2 V), thus allowing proper translation. From PECL to LVTTL This translation requires two devices for a direct, active connection. First, a level shift from PECL to LVPECL is done with the MC100LVEL92. Then, a translation from LVPECL to LVTTL is done with either the LVELT23, EPT21, EPT23, LVELT23, or EPT26 (see segment below). No sequencing is needed in powering up the MC100LVEL92, although both Positive supply levels, VCC and LVCC, must be connected for proper operation. http://onsemi.com 5 AN1672/D From LVPECL to LVTTL/LVCMOS present, such as during an open pin condition, the output falls to near zero without harm or damage to the device. Outputs of these devices typically display about 2X the required data sheet drive. For example, at VOLmin the drive is required to sink 24 mA and will typically sink >50 mA. At VOH, the spec drive is −3.0 mA and will typically source >8 mA. Typical drive current strength of the TTL output is shown in the following two tables, Table 7 and Table 8, and their graphs, Figure 3 and Figure 4. Devices MC100EPT21, MC100EPT23, MC100LVELT23, and MC100EPT26 translate LVPECL signals to LVTTL/LVCMOS. Standard levels for the LVTTL and LVCMOS are the same. There are no “open input” default circuits to force the outputs to a determined state. Provisions should be taken to prevent auto−oscillation. If the inputs are permitted to converged on the same voltage (within the VIHCMR range), or merely left floating, auto−oscillation will initiate. There are no powerup sequence requirements or power sequence restrictions. If either VCC or VEE supplies are not Typical EPT TTL series output impedance in the HIGH state is about 5 W. In the LOW state output impedance is about 15 W.AC measurements are made to the 1.5 V point for the AC characteristics such as tpd and skew. 200 Table 7. EPT TTL Series Drive LOW Current (IOL) vs Voltage (VOL) at 255C Vout (V) 4 0.022 20 0.104 39 0.200 58 0.295 82 0.415 118 0.596 158 0.800 196.3 1.000 160 IOL (mA) Iout (mA) 120 25°C 80 40 0 0 0.2 0.4 0.6 VOL (V) 0.8 1 Figure 3. EPT TTL Series Drive LOW Current (IOL) versus Voltage (VOL) at 255C −16 Table 8. EPT Series TTL Drive HIGH Current (IOH) vs Voltage (VOH) at 255C Vout (V) −14.6 2.32 −11.2 2.36 −8.1 2.40 −5.2 2.44 −2.8 2.48 −1.1 2.52 −0.3 2.56 −12 IOH (mA) Iout (mA) −8 −4 0 2.3 2.32 2.36 2.4 2.44 VOH (V) 2.48 2.52 2.56 Figure 4. EPT Series TTL Drive HIGH Current (IOH) versus Voltage (VOH) http://onsemi.com 6 AN1672/D From LVPECL to CMOS MC10H125 is the standard translator. Special advantages may be realized with the MC10H6xx series devices. Review the device data sheets for specific devices features. The MC10H125 operates over the frequency range from DC to about 50 MHz, although operation is possible >80 MHz with diminished output swing (reduced VOH levels) with higher frequency. Open, floating differential inputs on a gate may allow the device to spontaneously auto oscillate unless provisions are taken to prevent the inputs from converging. An external network may be used to force a default state on the outputs when the inputs are open. Use a 50 kW pulldown on the noninverting input, then a 50 kW pullup and a 50 kW pulldown on the inverting input. If a 3.3 V VCC is available, the MC100EPT25 may be used on this supply to receive NECL and drive a TTL receiver. The MC100EPT25 VOH will be limited to about 2.6 V at lower frequencies, decreasing at higher frequencies to 1.6 V VOH, at 550 MHz (see data sheet). These may be sufficient levels for a TTL receiver. Translation from LVPECL to CMOS will be similar to “PECL to CMOS” and that prior segment should be reviewed. The receiver input common mode range maximum must be sufficient to allow proper recognition of LVPECL HIGH levels (>2.2 V), thus allowing proper translation. The LVPECL to CMOS translation is accomplished through two stages, first LVPECL to LVTTL, then from LVTTL to CMOS. Final stage devices may any of the HCT type devices (i.e., MC74HCT245A), or ACT (i.e., MC74ACT244). From LVNECL to TTL MC100ELT25 will translate from LVNECL to TTL. Note the VIHCMR minimum is VEE + 2.2 V. If a 3.3 V supply is available for the MC100EPT25, this device will translate LVNECL to TTL, reaching a VOH of greater than 2.4 V up to 250 MHz. From LVNECL to LVTTL/LVCMOS MC100EPT25 will LVTTL/LVCMOS. translate from LVNECL to From NECL to LVTTL/LVCMOS MC100EPT25 will LVTTL/LVCMOS. From LVNECL to CMOS Use a first stage of MC100ELT25 (or MC100EPT23 if a 3.3 V supply is available) and then use a final stage device of an appropriate HCT (i.e., MC74HCT245A) or ACT (i.e., MC74ACT244). translate from NECL to From NECL to CMOS Use a MC100EPT25 to translate from NECL to LVTTL/LVCMOS, and then any of the HCT type devices (i.e., MC74HCT245A), or ACT (i.e., MC74ACT244) to boost the levels to CMOS. From NECL to TTL Several devices are offered for translation signals from NECL mode drivers to 5 V supplied TTL receivers, but the http://onsemi.com 7 AN1672/D Section 3: Translation from Non ECL Drivers to Different ECL Operating Mode Receivers Table 9. Translation from Non ECL Drivers to Different ECL Operating Mode Receivers From: To: TTL PECL VCC = +5 V LVPECL VCC = +2.5 V MC10H351 MC10H606 MC100H606 MC10ELT20 MC100ELT20 MC10ELT22 MC100ELT22 MC10ELT28 MC100ELT28* LVPECL VCC = +3.3 V LVNECL VEE = −3.3 V NECL VEE = −4.5 to −5.2 V MC10ELT20 MC100ELT20, or MC10ELT22 MC100ELT22, + MC100LVEL92; if VIH is limited to VCC = 3.3 V use MC10EPT20 MC100EPT20, MC10EPT22 MC100EPT22, or MC100LVELT22 MC10ELT20 MC100ELT20 or MC10ELT22 MC100ELT22 + MC100LVEL91 MC10H424 MC10H124 MC10H600 MC100H600 MC10H602 MC100H602 MC10H604 MC100H604 MC10ELT24 MC100ELT24 NB100LVEP91 NB100LVEP91 NB100LVEP91 LVTTL/LVCMOS/ HSTL/CML/LVDS VCC = 2.5 V LVTTL/LVCMOS VCC = 3.3 V MC10H351 MC10H606 MC100H606 MC10ELT20 MC100ELT20 MC10ELT22 MC100ELT22 MC10ELT28 MC100ELT28* OR: (MC10EPT20 MC100EPT20 or MC10EPT22 MC100EPT22 or MC100EP24 or MC100LVELT22) + 5 V PECL line receiver MC10EPT20 MC100EPT20 MC10EPT22 MC100EPT22 MC100LVELT22 MC100EPT622 MC10EPT24 MC100EPT24 or NB100LVEP91 NB100LVEP91 or MC10EPT24 MC100EPT24 + MC100EL91 CMOS VDD = +5 V MC10H352 MC10ELT20 MC100ELT20 MC10ELT22 MC100ELT22 MC10ELT28 MC100ELT28 MC10H352 + MC100LVEL92 MC10H352 + MC100LVEL91 MC10H352 + MC100EL91 *Bidirectional From TTL to PECL MC10H606 / MC100H606 as TTL to PECL This device offers translation and registration (reclocking) of TTL signals to PECL. Special advantages may be realized with this device, consult the device data sheets for specific features. MC10ELT20 / MC100ELT20 and MC10ELT22 / MC100ELT22 as TTL to PECL These devices do not sport any internal input resistor network to force a default level on an open floating pin. An open, floating TTL input (Pins 7, 8, 9, 12, 14) will drift to near VCC and considerations must be taken to reduce noise injected into the device under this condition, such as connecting unused inputs to VCC. Higher operating frequency range will be affected by input swing; a higher input swing will allow a higher operating range. An open, floating TTL input will drift to near VCC and may inject noise into the device under this condition. It is recommended to tie any unused TTL input to VCC. MC10H351 as TTL to PECL The MC10H351 operates over the frequency range from DC to >200 MHz. Although operation to higher frequencies is possible, the output VOH levels will decrease, rolling off as frequency increases. TTL VCC (Pin 11) would best be connected to the TTL logic devices positive supply, while ECL VCC is recommended to be isolated to a separate PECL logic plane, if possible. VEE, Pin 8, may be connected to the common ground plane. An open, floating TTL input (Pins 7, 8, 9, 12, 14) will drift to near VCC and considerations must be taken to reduce noise injected into the device under this condition, such as connecting unused inputs to VCC. The Common Strobe pin is TTL type input. Output to output skew is 150 ps worst case (at +70°C). Device to Device slew is less than 300 ps skew. Jitter is 40 to 60 ps. From TTL to LVPECL Translation from TTL to LVPECL requires a two−stage process: first TTL to PECL (with a 5 V supply) second PECL to LVPECL. The first may be accomplished per the http://onsemi.com 8 AN1672/D This reduces the operating voltage across the device from 5.0 V VEE supply to 3.3 V. This device does not have an internal input resistor network to force a default level on an open, floating input pin. If floated open, the TTL input, Pin 2, will drift to near VCC and may inject noise into the device. A 10 kW pullup resistor may be connected from Pin 2 to VCC forcing a default state (Q HIGH) under open or floating input conditions. segment above on TTL to PECL. The second stage is done with MC100LVEL92 (see also PECL to LVPECL segment). Under the condition where the TTL signal is confined to not exceed 3.3 V, a MC10EPT20 / MC100EPT20, MC10EPT22 / MC100EPT22, or MC100LVELT22 may be used. The MC100LVELT22 has operation frequency band range from <1 Hz (with sufficiently sharp edges) to 600 MHz. Diode clamping may be used to prevent input signals from exceeding 3.3 VCC. From TTL to LVNECL From LVTTL/LVCMOS to PECL Translation from TTL to LVNECL is done in two stages: 1. Use TTL to PECL (ELT20 or ELT22) 2. Then use PECL to LVNECL Translation (LVEL91). Both are described above. Alternatively, the first translation may be TTL to LVPECL and the second translation would then be LVPECL to LVNECL Translation, still using the LVEL91. If a −5 V supply is available, signals may be translated to NECL (see next segment) then ported to any LVNECL input. Translation from LVTTL to PECL may be done in a single device such as the H351, H606, ELT20, ELT22, or through half of the ELT28. For higher frequency operation, translation is done in two stages: 1. LVTTL to LVPECL using EPT20, EPT22, LVELT22, or EPT24 2. LVPECL signals into any PECL line receiver with a VIHCMRmin able to recognize a LVPECL HIGH level (such as EL17, EL14, EL13, etc.). From TTL to NECL Several devices are available to accomplish TTL to NECL translation in a single package: the −H424, −H124, and the ELT24. Alternatively, translation from TTL to NECL could be done in two stages: first TTL to PECL (ELT20 or ELT22), second by passing though a PECL to NECL Translation (EL91). The NECL or LVNECL output levels could then be ported to any NECL or LVNECL receiver, since the levels are the same. No power supply sequencing is needed, but all supply connections are required for proper operation. H424 as TTL to NECL An “open”, floating TTL input will drift to near VCC and considerations and may inject noise into the device under this condition. It is recommended to tie any unused TTL input to VCC. H124 as TTL to NECL Although no supply sequencing is required, if the VEE and GND are powered up prior to the VCC connected, about 5 to 10 mA may be drawn from a “off” VCC supply. This could draw the off VCC supply to −0.25 V, depending in the internal “off” impedance. H600 as TTL to NECL This device boasts a 9 bit wide capability with a bandwidth from <1 Hz (with sufficiently sharp edges) to 250 MHz. The ECL Enable input has an internal 50 kW pulldown resistor to force an input default (LOW) state when floating open. When both the TTL and ECL Enable pins are forced LOW, the outputs will default to LOW. H602 as TTL to NECL This device has similarities to the −H600 with pulldown resistors on the ENECL, LEN, and MR inputs. ELT24 as TTL to NECL Use the MC100EPT24D with a VEE “stand−off” resistor of about 61 W to drop the 1.7 V difference between VEE of LVPECL and PECL (mean IEE = 28 mA, sigma = 0.2 mA). From LVTTL/LVCMOS to LVPECL Use EPT20, EPT22, or LVELT22 to translate from LVTTL/LVCMOS to LVPECL From LVTTL/LVCMOS to LVNECL Use the MC100EPT24D or NB100LVEP91 From LVTTL to NECL Translation from LVTTL/LVCMOS to NECL is done in two stages: 1. Use LVTTL/LVCMOS to LVPECL (EPT20, EPT22, LVELT22) 2. Then use LVPECL to NECL (EL91). From CMOS to PECL The MC10H352 offers inputs with proper CMOS detect levels for translating 5.0 V CMOS signals to PECL levels. Non CMOS detect level devices may be used such as ELT20, ELT22, and ELT28 for expended frequency range with some small loss in duty cycle. From CMOS to LVPECL Translation from CMOS to LVPECL is done in two stages: 1. CMOS to PECL using a MC10H352 (or similar) 2. Then use a PECL to LVPECL translator, MC100LVEL92. From CMOS to LVNECL Translation from CMOS to LVNECL is done in two stages: 1. CMOS to PECL using a MC10H352 (or similar) 2. Then use PECL to LVNECL via MC100LVEL91. From CMOS to NECL Translation from CMOS to NECL is done in two stages: 1. CMOS to PECL using a MC10H352 (or similar); 2. Then use PECL to NECL translator, MC100EL91. http://onsemi.com 9 AN1672/D GigaComm is a trademark of Semiconductor Components Industries, LLC. ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages. “Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights nor the rights of others. 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