UT54ACS164245SEI Schmitt CMOS 16-bit Bidirectional MultiPurpose Transceiver Datasheet July, 2010 www.aeroflex.com/16BitLogic The direction and output enable controls operate these devices as either two independent 8-bit transceivers or one 16-bit transceiver. FEATURES • Flexible voltage operation - 5V bus to 3.3V bus; 5V bus to 5V bus - 3.3V bus to 5V bus; 3.3V bus to 3.3V bus • Cold sparing - 1MΩ minimum input impedance power-off • Warm sparing - Guaranteed output tri-state while one power supply is "off" and the other is "on" - 1MΩ minimum input impedance power-off • 0.6μm CRH CMOS Technology • Operational Environment: - Total dose: 100 krads(Si) - Single Event Latchup immune • High speed, low power consumption • Schmitt trigger inputs to filter noisy signals • Available QML Q or V processes • Standard Microcircuit Drawing 5962-98580 - Device Types 06 and 07 • Package: - 48-lead flatpack, 25 mil pitch (.390 x .640), wgt 1.4 grams LOGIC SYMBOL OE1 (48) G1 OE2 (25) (1) DIR1 G2 1A1 1A2 (3) (43) 1A4 (41) 1A5 (40) 1A6 (38) 1A7 (37) 1A8 (36) 2A1 (6) 2A3 (35) (33) (32) 2A4 (30) 2A5 (29) 2A6 (27) 2A7 (26) 2A8 1 12 (5) 2A2 The 16-bit wide UT54ACS164245SEI MultiPurpose transceiver is built using Aeroflex’s CRH technology. This high speed, low power UT54ACS164245SEI transceiver is designed to perform multiple functions including: asynchronous two-way communication, schmitt input buffering, voltage translation, cold and warm sparing. With either or both VDD1 and VDD2 are equal to zero volts, the UT54ACS164245SEI outputs and inputs present a minimum impedance of 1MΩ making it ideal for "cold spare" applications. Balanced outputs and low "on" output impedance make the UT54ACS164245SEI well suited for driving high capacitance loads and low impedance backplanes. The UT54ACS164245SEI enables system designers to interface 3.3 volt CMOS compatible components with 5 volt CMOS components. For voltage translation, the A port interfaces with the 3.3 volt bus; the B port interfaces with the 5 volt bus. The direction control (DIRx) controls the direction of data flow. The output enable (OEx) overrides the direction control and disables both ports. These signals can be driven from either port A or B. DIR2 (2) 11 (46) (24) (44) 1A3 DESCRIPTION (47) 2EN1 (BA) 2EN2 (AB) 1EN1 (BA) 1EN2 (AB) (8) 1B1 1B2 1B3 1B4 1B5 (9) 1B6 (11) 1B7 (12) 1B8 (13) 2B1 21 22 (14) 2B2 (16) 2B3 (17) 2B4 (19) 2B5 (20) 2B6 (22) 2B7 (23) 2B8 PIN DESCRIPTION Pin Names PINOUTS Description OEx Output Enable Input (Active Low) DIRx Direction Control Inputs xAx Side A Inputs or 3-State Outputs (3.3V Port) xBx Side B Inputs or 3-State Outputs (5V Port) 48-Lead Flatpack Top View FUNCTION TABLE ENABLE OEx DIRECTION DIRx OPERATION L L B Data To A Bus L H A Data To B Bus H X Isolation 2 DIR1 1 48 OE1 1B1 2 47 1A1 1B2 3 46 VSS 1B3 4 5 45 44 1A2 VSS 1B4 6 43 1A4 VDD1 7 42 VDD2 1B5 1B6 VSS 8 9 10 41 40 39 1A5 1A6 VSS 1B7 11 38 1A7 1B8 12 37 1A8 2B1 13 36 2A1 2B2 VSS 14 15 35 34 2A2 VSS 2B3 16 33 2A3 2B4 17 32 2A4 VDD1 2B5 2B6 VSS 18 19 20 21 31 30 29 28 VDD2 2A5 2A6 VSS 2B7 2B8 DIR2 22 23 24 27 26 25 2A7 2A8 OE2 1A3 POWER APPLICATION GUIDELINES For proper operation, connect power to all VDD pins and ground all VSS pins (i.e., no floating VDD or VSS input pins). By virtue of the UT54ACS164245SEI warm spare feature, power supplies VDD1 and VDD2 may be applied to the device in any order. To ensure the device is in cold spare mode, both supplies, VDD1 and VDD2 must be equal to VSS +/- 0.3V. Warm spare operation is in effect when one power supply is >1V and the other power supply is equal to VSS +/- 0.3V. If VDD1 has a power on ramp longer than 1 second, then VDD2 should be powered on first to ensure proper control of DIRx and OEx. During normal operation of the part, after power-up, ensure VDD1>VDD2. IO GUIDELINES All inputs are 5 volt tolerant. When VDD2 is at 3.3 volts, either 3.3 or 5 volt CMOS logic levels can be applied to all control inputs. It is recommended that all unused inputs be tied to VSS through a 1KΩ to 10KΩ resistor. It's good design practice to tie the unused input to VSS via a resistor to reduce noise susceptibility. The resistor protects the input pin by limiting the current from high going variations in VSS. The number of inputs that can be tied to the resistor pull-down can vary. It is up to the system designer to choose how many inputs are tied together by figuring out the max load the part can drivewhile still meeting system performance specs. Input signal transitions should be driven to the device with a rise and fall time that is <100ms. By definition, warm sparing occurs when half of the chip receives its normal VDD supply value while the VDD supplying the other half of the chip is set to 0.0V. When the chip is "warm spared", the side that has VDD set to a normal operational value is "actively" tri-stated because the chip’s internal OE signal is forced low. The side of the chip that has VDD set to 0.0V is "passively" tri-stated by the cold spare circuitry. In order to minimize transients and current consumption, the user is encouraged to first apply a high level to the OEx pins and then power down the appropriate supply. POWER TABLE Port B Port A OPERATION 5 Volts 3.3 Volts Voltage Translator 5 Volts 5 Volts Non Translating 3.3 Volts 3.3 Volts Non Translating VSS VSS Cold Spare VSS 3.3V or 5V Port A Warm Spare 3.3V or 5V VSS Port B Warm Spare 3 LOGIC DIAGRAM 2A1 3.3V PORT 1A4 (20) 2A7 (22) 2A8 (12) 4 2B7 (26) (23) 1B8 2B6 (27) 1B7 (37) 2B5 (29) 1B6 (38) 2B4 (30) (19) 2A6 (11) 1A8 (17) 2A5 2B3 (32) 1B5 (40) (9) 1A7 1B4 (41) (8) 1A6 (16) 2A4 2B2 (33) 1B3 (43) (6) 1A5 (14) 2A3 2B1 (35) 1B2 (44) OE2 (36) (13) 2A2 (5) (25) 1B1 (46) (3) 1A3 (24) OE1 (47) (2) 1A2 DIR2 3.3V PORT 1A1 (48) 2B8 5 V PORT (1) 5 V PORT DIR1 OPERATIONAL ENVIRONMENT1 PARAMETER LIMIT UNITS Total Dose 1.0E5 rad(Si) SEL Immune >114 MeV-cm2/mg Neutron Fluence2 1.0E14 n/cm2 Notes: 1. Logic will not latchup during radiation exposure within the limits defined in the table. 2. Not tested, inherent of CMOS technology. ABSOLUTE MAXIMUM RATINGS1 SYMBOL PARAMETER LIMIT (Mil only) UNITS VI/O (Port B)2 Voltage any pin during operation -.3 to VDD1 +.3 V VI/O (Port A)2 Voltage any pin during operation -.3 to VDD1 +.3 V VDD1 Supply voltage -0.3 to 6.0 V VDD2 Supply voltage -0.3 to 6.0 V TSTG Storage Temperature range -65 to +150 °C TJ Maximum junction temperature +175 °C ΘJC Thermal resistance junction to case 20 °C/W II DC input current ±10 mA PD Maximum power dissipation 1 W Note: 1. Stresses outside the listed absolute maximum ratings may cause permanent damage to the device. This is a stress rating only, functional operation of the device at these or any other conditions beyond limits indicated in the operational sections is not recommended. Exposure to absolute maximum rating conditions for extended periods may affect device reliability and performance. 2. For cold spare mode (VDD = VSS), VI/O may be -0.3V to the maximum recommended operating VDD + 0.3V. DUAL SUPPLY OPERATING CONDITIONS SYMBOL PARAMETER LIMIT UNITS VDD1 Supply voltage 3.0 to 3.6 or 4.5 to 5.5 V VDD2 Supply voltage 3.0 to 3.6 or 4.5 to 5.5 V VIN (Port B) Input voltage any pin 0 to VDD1 V VIN (Port A) Input voltage any pin 0 to VDD2 V TC Temperature range -55 to + 125 °C 5 DC ELECTRICAL CHARACTERISTICS 1 (Tc = -55°C to +125°C for "C" screening and -40°C to +125°C for "W" screening) SYMBOL PARAMETER CONDITION VT + Schmitt Trigger, positive going threshold2 VT- Schmitt Trigger, negative going threshold2 VDD from 3.0 to 5.5 VH1 Schmitt Trigger range of hysteresis VH2 IIN MIN VDD from 3.0 to 5.5 MAX UNIT .7VDD V .3VDD V VDD from 4.5 to 5.5 0.6 V Schmitt Trigger range of hysteresis VDD from 3.0 to 3.6 0.4 V Input leakage current VDD from 3.6 to 5.5 -1 3 μA -1 3 μA -1 5 μA -1 5 μA -200 200 mA -100 100 mA 0.4 V VIN = VDD or VSS IOZ Three-state output leakage current VDD from 3.6 to 5.5 VIN = VDD or VSS ICS Cold sparing leakage current3 VIN = 5.5 VDD = VSS IWS Warm sparing input leakage current (any pin)3 VIN = 5.5V VDD1 = VSS & VDD2 = 3.0V to 5.5V or VDD1 = 3.0V to 5.5V & VDD2 = VSS IOS1 Short-circuit output current 6, 10 VO = VDD or VSS VDD from 4.5 to 5.5 IOS2 Short-circuit output current 6, 10 VO = VDD or VSS VDD from 3.0 to 3.6 VOL1 Low-level output voltage4 IOL= 8mA IOL= 100μA 0.2 VDD = 4.5 VOL2 Low-level output voltage4 IOL= 8mA 0.5 IOL= 100μA 0.2 VDD = 3.0 VOH1 High-level output voltage4 V IOH= -8mA VDD - 0.7 IOH= -100μA VDD - 0.2 V VDD = 4.5 VOH2 High-level output voltage4 IOH= -8mA VDD - 0.9 IOH= -100μA VDD - 0.2 VDD = 3.0 6 V Ptotal1 Power dissipation 5,7, 8 CL = 50pF 2.0 mW/ MHz 1.5 mW/ MHz VDD from 4.5 to 5.5 Ptotal2 Power dissipation 5, 7, 8 CL = 50pF VDD from 3.00 to 3.6 IDDQ Standby Supply Current VDD1 or VDD2 VIN = VDD or VSS VDD = 5.5 CIN Pre-Rad 25oC OE = VDD 60 μA Pre-Rad -55oC to +125oC OE = VDD 100 μA Post-Rad 25oC OE = VDD 100 μA Input capacitance 9 ƒ = 1MHz @ 0V 15 pF 15 pF VDD from 3.0 to 5.5 COUT Output capacitance9 ƒ = 1MHz @ 0V VDD from 3.0 to 5.5 Notes: 1. All specifications valid for radiation dose ≤ 1E5 rad(Si) per MIL-STD-883, Method 1019. 2. Functional tests are conducted in accordance with MIL-STD-883 with the following input test conditions: VIH = VIH(min) + 20%, - 0%; VIL = VIL(max) + 0%, 50%, as specified herein, for TTL, CMOS, or Schmitt compatible inputs. Devices may be tested using any input voltage within the above specified range, but are guaranteed to VIH(min) and VIL(max). 3. This parameter is unaffected by the state of OEx or DIRx. 4. Per MIL-PRF-38535, for current density ≤ 5.0E5 amps/cm2, the maximum product of load capacitance (per output buffer) times frequency should not exceed 3,765 pF-MHz. 5. Guaranteed by characterization. 6. Not more than one output may be shorted at a time for maximum duration of one second. 7. Power does not include power contribution of any CMOS output sink current. 8. Power dissipation specified per switching output. 9.Capacitance measured for initial qualification and when design changes may affect the value. Capacitance is measured between the designated terminal and VSS at frequency of 1MHz and a signal amplitude of 50mV rms maximum. 10. Supplied as a design limit, but not guaranteed or tested. . 7 AC ELECTRICAL CHARACTERISTICS*1 (Port B = 5 Volt, Port A = 3.3 Volt) (VDD1 = 5V ±10%; VDD2 = 3.3V ± 0.3V) (Tc = -55°C to +125°C for "C" screening and -40°C to +125°C for "W" screening) SYMBOL PARAMETER MIN MAX UNIT UT54ACS164245SEI tPLH Propagation delay Data to Bus 3.5 11 ns tPHL Propagation delay Data to Bus 3.5 11 ns tPZL Output enable time OEx to Bus 2.5 16 ns tPZH Output enable time OEx to Bus 2.5 16 ns tPLZ Output disable time OEx to Bus high impedance 2.5 16 ns tPHZ Output disable time OEx to Bus high impedance 2.5 16 ns tPZL2 Output enable time DIRx to Bus 1 18 ns tPZH2 Output enable time DIRx to Bus 1 18 ns tPLZ2 Output disable time DIRx to Bus high impedance 1 20 ns tPHZ2 Output disable time DIRx to Bus high impedance 1 20 ns tSKEW3 Skew between outputs - 600 ps tDSKEW4 Differential skew between outputs - 1.5 ns Notes: * For devices procured with a total ionizing dose tolerance guarantee, the post-irradiation performance is guaranteed at 25oC per MIL-STD-883 Method 1019, Condition A up to the maximum TID level procured. 1. All specifications valid for radiation dose ≤ 1E5 rad(Si) per MIL-STD-883, Method 1019. 2. DIRx to bus times are guaranteed by design, but not tested. OEx to bus times are tested 3. Output skew is defined as a comparison of any two output transitions of the same type at the saame temperature and voltage for the same port within the same byte: 1A1 through 1A8 are compared high-to-low versus high-to-low and low-to-high versus low-to-high; similarly 1B1 through 1B8 are compared, 2A1 through 2A8 are compared, and 2B1 through 2B8 are compared. 4. Differential output skew is defined as a comparison of any two output transitions of opposite types on the same type at the same temperature and voltage for the same port within the same byte: 1A1 through 1A8 are compared high-to-low versus low-to-high; similarly 1B1 through 1B8 are compared, 2A1 through 2A8 are compared, and 2B1 through 2B8 are compared. . 8 Propagation Delay Input tPLH VDD VDD/2 0V tPHL VOH VDD/2 VOL Output Enable Disable Times Control Input 5V Output Normally Low 5V Output Normally High tPZL tPLZ VDD/2-0.2 tPHZ tPZH VDD/2+0.2 .8VDD - .2V tPLZ tPZL 3.3V Output Normally Low 3.3V Output Normally High .2VDD + .2V VDD/2-0.2 .2VDD + .2V tPHZ tPZH VDD/2+0.2 9 .7VDD - .2V VDD VDD/2 0V VDD/2 .2VDD .8VDD VDD/2 VDD/2 .2VDD .7VDD VDD/2 AC ELECTRICAL CHARACTERISTICS*1 (Port A = Port B, 5 Volt Operation) (VDD1 = 5V ± 10%; VDD2 = 5.0V ± 10%) (Tc = -55°C to +125°C for "C" screening and -40°C to +125°C for "W" screening) SYMBOL PARAMETER MIN MAX UNIT UT54ACS164245SEI tPLH Propagation delay Data to Bus 3.5 9 ns tPHL Propagation delay Data to Bus 3.5 9 ns tPZL Output enable time OEx to Bus 3 9 ns tPZH Output enable time OEx to Bus 3 9 ns tPLZ Output disable time OEx to Bus high impedance 3 9 ns tPHZ Output disable time OEx to Bus high impedance 3 9 ns tPZL2 Output enable time DIRx to Bus 1 12 ns tPZH2 Output enable time DIRx to Bus 1 12 ns tPLZ2 Output disable time DIRx to Bus high impedance 1 15 ns tPHZ2 Output disable time DIRx to Bus high impedance 1 15 ns tSKEW3 Skew between outputs - 600 ps tDSKEW4 Differential skew between outputs - 1.5 ns Notes: * For devices procured with a total ionizing dose tolerance guarantee, the post-irradiation performance is guaranteed at 25oC per MIL-STD-883 Method 1019, Condition A up to the maximum TID level procured. 1. All specifications valid for radiation dose ≤ 1E5 rad(Si) per MIL-STD-883, Method 1019. 2. DIRx to bus times are guaranteed by design, but not tested. OEx to bus times are tested 3. Output skew is defined as a comparison of any two output transitions of the same type at the saame temperature and voltage for the same port within the same byte: 1A1 through 1A8 are compared high-to-low versus high-to-low and low-to-high versus low-to-high; similarly 1B1 through 1B8 are compared, 2A1 through 2A8 are compared, and 2B1 through 2B8 are compared. 4. Differential output skew is defined as a comparison of any two output transitions of opposite types on the same type at the same temperature and voltage for the same port within the same byte: 1A1 through 1A8 are compared high-to-low versus low-to-high; similarly 1B1 through 1B8 are compared, 2A1 through 2A8 are compared, and 2B1 through 2B8 are compared. 10 Propagation Delay Input tPLH VDD VDD/2 0V tPHL VOH VDD/2 VOL Output Enable Disable Times Control Input 5V Output Normally Low 5V Output Normally High tPZL tPLZ .2VDD + .2V VDD/2-0.2 tPHZ tPZH VDD/2+0.2 VDD VDD/2 0V VDD/2 .2VDD .8VDD .8VDD - .2V VDD/2 Propagation Delay Input tPLH VDD VDD/2 0V tPHL VOH VDD/2 VOL Output Enable Disable Times Control Input 3.3V Output Normally Low 3.3V Output Normally High tPZL tPLZ VDD/2-0.2 .2VDD + .2V tPHZ tPZH VDD/2+0.2 11 .7VDD - .2V VDD VDD/2 0V VDD/2 .2VDD .7VDD VDD/2 AC ELECTRICAL CHARACTERISTICS*1 (Port A = Port B, 3.3 Volt Operation) (VDD1 = 3.3V + 0.3V; VDD2 = 3.3V + 0.3V) (Tc = -55°C to +125°C for "C" screening and -40°C to +125°C for "W" screening) SYMBOL PARAMETER MIN MAX UNIT UT54ACS164245SEI tPLH Propagation delay Data to Bus 3.5 11 ns tPHL Propagation delay Data to Bus 3.5 11 ns tPZL Output enable time OEx to Bus 2.5 16 ns tPZH Output enable time OEx to Bus 2.5 16 ns tPLZ Output disable time OEx to Bus high impedance 2.5 16 ns tPHZ Output disable time OEx to Bus high impedance 2.5 16 ns tPZL2 Output enable time DIRx to Bus 1 18 ns tPZH2 Output enable time DIRx to Bus 1 18 ns tPLZ2 Output disable time DIRx to Bus high impedance 1 20 ns tPHZ2 Output disable time DIRx to Bus high impedance 1 20 ns tSKEW3 Skew between outputs 600 ps tDSKEW4 Differential skew between outputs 1.5 ns Notes: * For devices procured with a total ionizing dose tolerance guarantee, the post-irradiation performance is guaranteed at 25oC per MIL-STD-883 Method 1019, Condition A up to the maximum TID level procured. 1. All specifications valid for radiation dose ≤ 1E5 rad(Si) per MIL-STD-883, Method 1019. 2. DIRx to bus times are guaranteed by design, but not tested. OEx to bus times are tested. 3. Output skew is defined as a comparison of any two output transitions of the same type at the saame temperature and voltage for the same port within the same byte: 1A1 through 1A8 are compared high-to-low versus high-to-low and low-to-high versus low-to-high; similarly 1B1 through 1B8 are compared, 2A1 through 2A8 are compared, and 2B1 through 2B8 are compared. 4. Differential output skew is defined as a comparison of any two output transitions of opposite types on the same type at the same temperature and voltage for the same port within the same byte: 1A1 through 1A8 are compared high-to-low versus low-to-high; similarly 1B1 through 1B8 are compared, 2A1 through 2A8 are compared, and 2B1 through 2B8 are compared. 12 PACKAGE 5 6 4 6 1. All exposed metalized areas are gold plated over electroplated nickel per MIL-PRF-38535. 2. The lid is electrically connected to VSS. 3. Lead finishes are in accordance with MIL-PRF-38535. 4. Lead position and colanarity are not measured. 5. ID mark symbol is vendor option. 6. With solder, increase maximum by 0.003. Figure 1. 48-Lead Flatpack 13 ORDERING INFORMATION UT54ACS164245SEI: SMD 5962 R 98580 ** * * * Lead Finish: (C) = Gold Case Outline: (X) = 48 lead BB FP (Gold only) Class Designator: (Q) = Class Q (V) = Class V Device Type (06) = 16-bit MultiPurpose Transceiver with warm and cold sparing (Full Mil-Temp) (07) = 16-bit MultiPurpose Transceiver with warm and cold sparing (Extended Industrial Temp) Drawing Number: 98580 Total Dose: (Note 1) (R) = 1E5 rad(Si) Federal Stock Class Designator: No options Notes: 1. Total dose radiation must be specified when ordering. QML Q and QML V not available without radiation hardening. 14 UT54ACS164245SEI UT54 *** ****** -* * * Lead Finish: (C) = Gold Screening: (C) = HiRel Temp (-55oC to +125oC) (P) = Prototype (Room temp Only) (W) = Extended Industrial Temp (-40oC to +125oC) Package Type: (U) = 48-lead BB FP (Gold only) Part Number: (164245SEI) = 16-bit MultiPurpose Transceiver with warm and cold sparing I/O Type: (ACS)= CMOS compatible I/O Level Aeroflex Core Part Number Notes: 1. HiRel Temperature Range flow per Aeroflex Manufacturing Flows Document. Devices are tested -55C, room temp, and 125C. Radiation neither tested nor guaranteed. 2. Extended Industrial Temperature Range Flow per Aeroflex Manufacturing Flows Document. Devices are tested at -40oC, room temp, and +125oC. Radiation is neither tested nor guaranteed. 3. Extended Industrial Range flow per Aeroflex Colorado Springs Manufacturing Flows Document. Devices are tested at -40°C, room temp, and 125°C. Radiation neither tested nor guaranteed. 15 Aeroflex Colorado Springs - Datasheet Definition Advanced Datasheet - Product In Development Preliminary Datasheet - Shipping Prototype Datasheet - Shipping QML & Reduced Hi-Rel COLORADO Toll Free: 800-645-8862 Fax: 719-594-8468 INTERNATIONAL Tel: 805-778-9229 Fax: 805-778-1980 NORTHEAST Tel: 603-888-3975 Fax: 603-888-4585 SE AND MID-ATLANTIC Tel: 321-951-4164 Fax: 321-951-4254 WEST COAST Tel: 949-362-2260 Fax: 949-362-2266 CENTRAL Tel: 719-594-8017 Fax: 719-594-8468 www.aeroflex.com [email protected] Aeroflex Colorado Springs, Inc. reserves the right to make changes to any products and services herein at any time without notice. Consult Aeroflex or an authorized sales representative to verify that the information in this data sheet is current before using this product. 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