HI-1579, HI-1581 MIL-STD-1553 / 1760 3.3V Monolithic Dual Transceivers May 2013 DESCRIPTION PIN CONFIGURATIONS To minimize the package size for this function, the transmitter outputs are internally connected to the receiver inputs, so that only two pins are required for connection to each coupling transformer. FEATURES · Compliant to MIL-STD-1553A and B, MIL-STD-1760 and ARINC 708A · 3.3V single supply operation 44 pin plastic chip-scale package (QFN) · 1.0W typical power dissipation (50% duty cycle) and extended temperature 44 Pin Plastic 7mm x 7mm Chip-scale package VDDA 1 BUSA 2 BUSA 3 RXENA 4 GNDA 5 VDDB 6 BUSB 7 BUSB 8 RXENB 9 GNDB 10 1579PSI 1579PST 1579PSM 1581PSI 1581PST 1581PSM 20 19 18 17 16 15 14 13 12 11 TXA TXA TXINHA RXA RXA TXB TXB TXINHB RXB RXB VDDA 1 20 TXA BUSA 2 19 TXA BUSA 3 RXENA 4 BUSB 7 Industry standard pin configurations 1579CDI 1579CDT 1579CDM BUSB 8 18 TXINHA 17 RXA 16 RXA GNDA 5 VDDB 6 ranges · 1581PCI 1581PCT 1581PCM 20 Pin Plastic ESOIC - WB package · Smallest footprint available in 7mm x 7mm · Industrial 33 32 31 TXINHA 30 RXA 29 RXA 28 27 26 TXB 25 TXB 24 TXINHB 23 - 1579PCI 1579PCT 1579PCM 12 13 14 15 16 17 18 19 20 21 22 The receiver section of the each bus converts the 1553 bus bi-phase data to complementary CMOS / TTL data suitable for input to a Manchester decoder. Each receiver has a separate enable input, which forces the receiver outputs to logic "0" (HI-1579) or logic 1 (HI-1581). - 1 RXENA 2 GNDA 3 GNDA 4 GNDA 5 VDDB 6 VDDB 7 BUSB 8 BUSB 9 BUSB 10 BUSB 11 RXENB GNDB GNDB GNDB RXB RXB - The transmitter section of each bus takes complementary CMOS / TTL Manchester II bi-phase data and converts it to differential voltages suitable for driving the bus isolation transformer. Separate transmitter inhibit control signals are provided for each transmitter. 44 43 BUSA 42 BUSA 41 BUSA 40 BUSA 39 VDDA 38 VDDA 37 TXA 36 TXA 35 34 - The HI-1579 and HI-1581 are low power CMOS dual transceivers designed to meet the requirements of the MIL-STD-1553 and MIL-STD-1760 specifications. 1581CDI 1581CDT 1581CDM 15 TXB 14 TXB 13 TXINHB RXENB 9 12 RXB GNDB 10 11 RXB 20 Pin Ceramic DIP package (DS1579 Rev. K) HOLT INTEGRATED CIRCUITS www.holtic.com 05/13 HI-1579, HI-1581 PIN DESCRIPTIONS PIN (DIP & SOIC) 1 SYMBOL FUNCTION DESCRIPTION VDDA power supply +3.3 volt power for transceiver A 2 BUSA analog output MIL-STD-1533 bus driver A, positive signal 3 BUSA analog output 4 RXENA digital input 5 GNDA power supply Ground for transceiver A 6 VDDB power supply +3.3 volt power for transceiver B 7 BUSB analog output MIL-STD-1533 bus driver B, positive signal 8 BUSB analog output MIL-STD-1553 bus driver B, negative signal 9 RXENB digital input 10 GNDB power supply Ground for transceiver B 11 RXB digital output Receiver B output, inverted 12 RXB digital output Receiver B output, non-inverted 13 TXINHB digital input Transmit inhibit, bus B. If high BUSB, BUSB disabled 14 TXB digital input Transmitter B digital data input, non-inverted 15 TXB digital input Transmitter B digital data input, inverted 16 RXA digital output Receiver A output, inverted 17 RXA digital output Receiver A output, non-inverted 18 TXINHA digital input Transmit inhibit, bus A. If high BUSA, BUSA disabled 19 TXA digital input Transmitter A digital data input, non-inverted 20 TXA digital input Transmitter A digital data input, inverted MIL-STD-1553 bus driver A, negative signal Receiver A enable. If low, forces RXA and RXA low Receiver B enable. If low, forces RXB and RXB low FUNCTIONAL DESCRIPTION The HI-1579 family of dual data bus transceivers contains differential voltage source drivers and differential receivers. It is intended for applications using a MIL-STD-1553 A/B data bus. The device produces a trapezoidal output waveform during transmission. TRANSMITTER Data input to the device’s transmitter section is from the complementary CMOS inputs TXA/B and TXA/B. The transmitter accepts Manchester II bi-phase data and converts it to differential voltages on BUSA/B and BUSA/B. The transceiver outputs are either direct- or transformercoupled to the MIL-STD-1553 data bus. Both coupling methods produce a nominal voltage on the bus of 7.5 volts peak to peak. The transmitter is automatically inhibited and placed in the high impedance state when both TXA/B and TXA/B are driven with the same logic state. A logic “1” applied to the TXINHA/B input forces the transmitter to the high impedance state, regardless of the state of TXA/B and TXA/B. RECEIVER The receiver accepts bi-phase differential data from the MIL-STD-1553 bus through the same direct- or transformer- coupled interface as the transmitter. The receiver’s differential input stage drives a filter and threshold comparator to produce CMOS data at the RXA/B and RXA/B output pins. When the MIL-STD-1553 bus is idle and RXENA or RXENB are high, RXA/B will be logic “0” on HI-1579 and logic “1” on HI-1581. The receiver outputs are forced to the bus idle state (logic "0” for HI-1579 or logic “1” for HI-1581) when the RXENA or RXENB is low. MIL-STD-1553 BUS INTERFACE A direct-coupled interface (see Figure 2) uses a 1:2.5 ratio isolation transformer and two 55 ohm isolation resistors between the transformer and the bus. The primary center-tap of the isolation transformer must be connected to GND. In a transformer-coupled interface (see Figure 2), the transceiver is also connected to a 1:2.5 isolation transformer which in turn is connected to a 1:1.4 coupling transformer. The transformer coupled method also requires two coupling resistors equal to 75% of the bus characteristic impedance (Zo) between the coupling transformer and the bus. Figure 3 and Figure 4 show test circuits for measuring electrical characteristics of both direct- and transformercoupled interfaces respectively. (See electrical characteristics on the following pages). HOLT INTEGRATED CIRCUITS 2 HI-1579, HI-1581 Data Bus Each Bus TRANSMITTER Isolation Transformer Coupler Network BUSA/B TXA/B Transmit Logic Direct or Transformer Slope Control TXA/B BUSA/B TXINHA/B RECEIVER RXA/B Input Filter Receive Logic RXA/B Comparator RXENA/B Figure 1. Block Diagram TRANSMIT WAVEFORM - EXAMPLE PATTERN TXA/B TXA/B BUSA/B - BUSA/B RECEIVE WAVEFORMS - EXAMPLE PATTERN Vin (Line to Line) tDR tDR tDR RXA/B (HI-1579) tRG tRG tRG tRG RXA/B (HI-1579) RXA/B (HI-1581) RXA/B (HI-1581) HOLT INTEGRATED CIRCUITS 3 tDR HI-1579, HI-1581 RECOMMENDED OPERATING CONDITIONS ABSOLUTE MAXIMUM RATINGS Supply voltage (VDD) Supply Voltage -0.3 V to +5 V Logic input voltage range VDD....................................... 3.3V... ±5% -0.3 V dc to +3.6 V Receiver differential voltage Temperature Range 50 Vp-p Driver peak output current +1.0 A Power dissipation at 25°C ceramic DIL, derate 1.0 W 7mW/°C Solder Temperature Industrial ........................ -40°C to +85°C Hi-Temp ....................... -55°C to +125°C NOTE: Stresses above absolute maximum ratings or outside recommended operating conditions may cause permanent damage to the device. These are stress ratings only. Operation at the limits is not recommended. 275°C for 10 sec. Junction Temperature 175°C Storage Temperature -65°C to +150°C DC ELECTRICAL CHARACTERISTICS VDD = 3.3 V, GND = 0V, TA = Operating Temperature Range (unless otherwise specified). PARAMETER SYMBOL CONDITION MIN TYP MAX UNITS 3.15 3.30 3.45 V Operating Voltage VDD Total Supply Current ICC1 Not Transmitting 4 17 mA ICC2 Transmit one bus @ 50% duty cycle 225 320 mA ICC3 Transmit one bus @ 100% duty cycle 425 640 mA 0.06 W 1.0 W Power Dissipation PD1 Not Transmitting PD2 Transmit one bus @ 100% duty cycle 0.5 Min. Input Voltage (HI) VIH Digital inputs Max. Input Voltage (LO) VIL Digital inputs Min. Input Current (HI) IIH Digital inputs Max. Input Current (LO) IIL Digital inputs -20 µA Min. Output Voltage (HI) VOH IOUT = -1.0mA, Digital outputs 90% VDD (LO) VIH IOUT = 1.0mA, Digital outputs Max. Output Voltage RECEIVER 70% VDD 30% VDD 20 µA 10% VDD (Measured at Point “AD“ in Figure 2 unless otherwise specified) Input resistance RIN Differential (at chip pins) Input capacitance CIN Differential Common mode rejection ratio CMRR Input Level VIN Input common mode voltage Differential -10.0 Detect VTHD 1 MHz Sine Wave Measured at Point “AD“ in Figure 2 RXA/B, RXA/B pulse width >70 ns No Detect VTHND No pulse at RXA/B, RXA/B Theshold Voltage - Transformer-coupled Kohm 5 40 VICM Threshold Voltage - Direct-coupled 2 Detect VTHD 1 MHz Sine Wave Measured at Point “AT“ in Figure 3 RXA/B, RXA/B pulse width >70 ns No Detect VTHND No pulse at RXA/B, RXA/B HOLT INTEGRATED CIRCUITS 4 pF dB 9 Vp-p 10.0 V-pk 1.15 Vp-p 0.28 0.86 Vp-p Vp-p 0.20 Vp-p HI-1579, HI-1581 DC ELECTRICAL CHARACTERISTICS (cont.) VDD = 3.3 V, GND = 0V, TA = Operating Temperature Range (unless otherwise specified). PARAMETER TRANSMITTER SYMBOL CONDITION MIN TYP MAX UNITS 6.1 9.0 Vp-p 20.0 27.0 Vp-p 10.0 mVp-p -90 90 mV -250 250 mV 15 pF (Measured at Point “AD” in Figure 2 unless otherwise specified) Output Voltage Direct coupled VOUT Transformer coupled VOUT Output Noise 35 ohm load (Measured at Point “AD“ in Figure 2) 70 ohm load (Measured at Point “AT“ in Figure 3) VON Output Dynamic Offset Voltage Differential, inhibited Direct coupled VDYN Transformer coupled VDYN Output Capacitance 35 ohm load (Measured at Point “AD“ in Figure 2) 70 ohm load (Measured at Point “AT“ in Figure 3) COUT 1 MHz sine wave AC ELECTRICAL CHARACTERISTICS VDD = 3.3 V, GND = 0V, TA =Operating Temperature Range (unless otherwise specified). PARAMETER RECEIVER SYMBOL TEST CONDITIONS MIN TYP MAX UNITS 450 ns 365 ns 40 ns (Measured at Point “AD” in Figure 2 unless otherwise specified) Receiver Delay tDR From input zero crossing to RXA/B or RXA/B Receiver gap time tRG Spacing between RXA/B 90 and RXA/B pulses. 1 MHz sine wave applied at point “AT” Figure 3, amplitude range 0.86 Vp-p to 27.0Vp-p Receiver Enable Delay tREN From STROBE rising or falling edge to RXA/B or RXA/B TRANSMITTER Driver Delay (Measured at Point “AD” in Figure 2) tDT TXA/B, TXA/B to BUSA/B, BUSA/B 150 ns Rise time tr 35 ohm load 100 300 ns Fall Time tf 35 ohm load 100 300 ns tDI-H Inhibited output 100 ns tDI-L Active output 150 ns Inhibit Delay MIL-STD-1553 BUS A (Direct Coupled) Isolation Transformer BUS A 55W BUS A 55W Transceiver A 1:2.5 MIL-STD-1553 Stub Coupler Isolation Transformer BUS B 52.5W BUS B 52.5W MIL-STD-1553 BUS B (Transformer Coupled) Transceiver B 1:2.5 1:1.4 HI-1579 / HI-1581 Figure 2. Bus Connection Example using HI-1579 or HI-1581 HOLT INTEGRATED CIRCUITS 5 HI-1579, HI-1581 VDD Each Bus Isolation Transformer TXA/B TXA/B RXA/B MIL-STD-1553 Transceiver BUS A/B 55W BUS A/B 55W 35W RXA/B 1:2.5 Point “AD” HI-1579 / HI-1581 GND Figure 3. Direct Coupled Test Circuit VDD Each Bus Isolation Transformer TXA/B TXA/B RXA/B MIL-STD-1553 Transceiver RXA/B BUS A/B 70W BUS A/B 1:2.5 Point “AT” HI-1579 / HI-1581 GND Figure 4. Transformer Coupled Test Circuit HEAT SINK ESOIC & CHIP-SCALE PACKAGES and may be soldered to any convenient power or ground plane. The HI-1579PSI/T/M and HI-1581PSI/T/M use a 20-pin thermally enhanced SOIC package. The HI-1579PCI/T/M and HI-1581PCI/T/M use a plastic chip-scale package (QFN). These packages include a metal heat sink located on the bottom surface of the device. This heat sink may be soldered down to the printed circuit board for optimum thermal dissipation. The heat sink is electrically isolated APPLICATIONS NOTE Holt Applications Note AN-500 provides circuit design notes regarding the use of Holt's family of MIL-STD-1553 transceivers. Layout considerations, as well as recommended interface and protection components are included. THERMAL CHARACTERISTICS PART NUMBER PACKAGE STYLE HI-1579PSI / T / M 20-pin Thermally enhanced plastic SOIC ( ESOIC) HI-1581PSI / T /M HI-1579CDI / T / M HI-1579CDI / T / M HI-1579PCI / T / M HI-1581PCI / T / M JUNCTION TEMPERATURE TA=25°C TA=85°C TA=125°C CONDITION ØJA Heat sink unsoldered 54°C/W 68°C 130°C 170°C Heat sink soldered 47°C/W 63°C 124°C 165°C 20-pin Ceramic side-brazed Socketed 62°C/W 74°C 136°C 175°C 44-Plastic chipscale package (QFN) Heat sink unsoldered 49°C/W 65°C 126°C 166°C Data taken at VDD=3.3V, continuous transmission at 1Mbit/s, single transmitter enabled. HOLT INTEGRATED CIRCUITS 6 HI-1579, HI-1581 ORDERING INFORMATION HI - 15xx xx x x (Plastic) PART NUMBER Blank F PART NUMBER LEAD FINISH Tin / Lead (Sn / Pb) Solder 100% Matte Tin (Pb-free RoHS compliant) TEMPERATURE RANGE FLOW BURN IN I -40°C TO +85°C I No T -55°C TO +125°C T No M -55°C TO +125°C M Yes PART NUMBER PACKAGE DESCRIPTION PC 44 PIN PLASTIC CHIP-SCALE PACKAGE QFN (44PCS) PS 20 PIN PLASTIC ESOIC, Thermally Enhanced Wide SOIC w/Heat Sink (20HWE) PART NUMBER RXENA = 0 RXA RXA RXENB = 0 RXB RXB 1579 0 0 0 0 1581 1 1 1 1 HI - 15xxCD x (Ceramic) PART NUMBER TEMPERATURE RANGE FLOW BURN IN I -40°C TO +85°C I No Gold (Pb-free, RoHS compliant) T -55°C TO +125°C T No Gold (Pb-free, RoHS compliant) M -55°C TO +125°C M Yes Tin / Lead (Sn / Pb) Solder PART NUMBER RXENA = 0 RXA RXA RXENB = 0 RXB RXB LEAD FINISH PACKAGE DESCRIPTION 1579 0 0 0 0 20 PIN CERAMIC SIDE BRAZED DIP (20C) 1581 1 1 1 1 20 PIN CERAMIC SIDE BRAZED DIP (20C) RECOMMENDED TRANSFORMERS The HI-1579 and HI-1581 transceivers have been characterized for compliance with the electrical requirements of MIL-STD-1553 when used with the following transformers. Holt recommends Premier Magnetics parts as offering the best combination of electrical performance, low cost and small footprint. MANUFACTURER PART NUMBER APPLICATION TURNS RATIO DIMENSIONS Premier Magnetics PM-DB2791S Isolation Single 1:2.5 .400 x .400 x .185 inches Premier Magnetics PM-DB2756 Isolation Dual 1:2.5 .930 x .575 x .185 inches Premier Magnetics PM-DB2702 Stub coupling 1:1.4 .625 x .500 x .250 inches HOLT INTEGRATED CIRCUITS 7 HI-1579, HI-1581 REVISION HISTORY Document Rev. Date Description of Change DS1579 Correct typographical errors in package dimensions. Clarified available temperature ranges. Clarified status of RXA/B and RXA/B pins in bus idle state when RXENA or RXENB are high (logic “1”). Clarified nomenclature of chip-scale package as QFN. Added ’M’ flow option for QFN package (’PCM’ package option). Updated datasheet to include HI-1581 variant. Corrected dynamic current and power dissipation values. Revised Thermal Characteristic table to correspond to correct dynamic currents and power dissipation values. Revised DC Electrical Characteristics table to correspond to actual measured values. Revised Bus Connection and Test Circuit Diagrams. Revised SOIC package standoff dimension. Revised text in functional description to improve clarity. Added more detail to AC timing parameter table. Removed reference to non-preferred transformers Updated package drawings.. F 07/24/09 G 10/5/09 H I 01/26/10 02/01/10 J 08/18/10 K 05/23/13 HOLT INTEGRATED CIRCUITS 8 PACKAGE DIMENSIONS 20-PIN PLASTIC SMALL OUTLINE (ESOIC) - WB (Wide Body, Thermally Enhanced) inches (millimeters) Package Type: 20HWE .008 ± .005 (.215 ± .115) .295 ± .015 (7.495 ± .385) .504 BSC (12.80) .407 BSC (10.33) Bottom View .210 ± .015 (5.335 ± .385) .295 BSC (7.50) Top View See Detail A .016 ± .004 (.419 ± .109) Electrically isolated heat sink pad on bottom of package .086 ± .005 (2.181 ± .131) .050 BSC (1.27) 0° to 8° .008 ± .004 (.200 ± .100) .033 ± .017 (.835 ± .435) BSC = “Basic Spacing between Centers” is theoretical true position dimension and has no tolerance. (JEDEC Standard 95) Connect to any ground or power plane for optimum thermal dissipation Detail A 20-PIN CERAMIC SIDE-BRAZED DIP inches (millimeters) Package Type: 20C 1.000 ±.010 (25.400 ±.254) .310 ±.010 (7.874 ±.254) .050 TYP. (1.270 TYP.) .125 min (3.175) BSC = “Basic Spacing between Centers” is theoretical true position dimension and has no tolerance. (JEDEC Standard 95) .300 ± .010 (7.620 ± .254) .085 ±.009 (2.159 ± .229) .200 max (5.080) .100 BSC (2.54) .017 ±.002 (.432 ±.051) HOLT INTEGRATED CIRCUITS 9 .010 + 0. 02/-.001 (.254 ±.051/-.025) PACKAGE DIMENSIONS 44-PIN PLASTIC CHIP-SCALE PACKAGE (QFN) inches (millimeters) Package Type: 44PCS .276 BSC (7.00) .216 ± .002 (5.50 ± .05) .020 BSC (0.50) .276 BSC (7.00) .216 ± .002 (5.50 ± .05) Top View Bottom View .010 (0.25) typ .039 max (1.00) .008 typ (0.2) BSC = “Basic Spacing between Centers” is theoretical true position dimension and has no tolerance. (JEDEC Standard 95) Electrically isolated heat sink pad on bottom of package Connect to any ground or power plane for optimum thermal dissipation HOLT INTEGRATED CIRCUITS 10 .016 ± .002 (0.40 ± .05)