A5191HRT HART Modem 1.0 Key Features • • • • • • • • • • • • Can be used in designs presently using the SYM20C15 Single-chip, half-duplex 1200 bits per second FSK modem Bell 202 shift frequencies of 1200Hz and 2200Hz 3.3V - 5.0V power supply Transmit-signal wave shaping Receive band-pass filter Low power: optimal for intrinsically safe applications CMOS compatible Internal oscillator requires 460.8kHz crystal or ceramic resonator Meets HART physical layer requirements Industrial temperature range of -40°C to +85°C Available in 28-pin PLCC and 32-pin LQFP packages 2.0 Description The A5191HRT is a single-chip, CMOS modem for use in highway addressable remote transducer (HART) field instruments and masters. The modem and a few external passive components provide all of the functions needed to satisfy HART physical layer requirements including modulation, demodulation, receive filtering, carrier detect, and transmit-signal shaping. The A5191HRT is pincompatible with the SYM20C15. See the Pin Description and Functional Description sections for details on pin compatibility with the SYM20C15. The A5191HRT uses phase continuous frequency shift keying (FSK) at 1200 bits per second. To conserve power the receive circuits are disabled during transmit operations and vice versa. This provides the half-duplex operation used in HART communications. Figure 1: 28-Pin PLCC Pin Out Diagrams (Green & Non-Green) ©2008 SCILLC. All rights reserved. May 2008 – Rev. 3 Publication Order Number: A5191HRT/D A5191HRT Figure 2: 32-Pin LQFP Pin Out Diagrams (Green & Non-Green) Table 1: Pin Out Summary 28-Pin PLCC, A5191HRTP/Pg (12197-504/508) Pin No. Signal Name Type Pin Description 1 TEST1 Input Connect to VSS 2 TEST2 No connect 3 TEST3 No connect 4 TEST4 No connect 5 TEST5 Input Connect to VSS 6 INRESET Input Reset all digital logic when low 7 TEST7 Input Connect to VSS 8 TEST8 Input Connect to VSS 9 TEST9 Input Connect to VSS 10 OTXA Output Output transmit analog, FSK modulated HART transmit signal to 4-20mA loop interface circuit 11 IAREF Input Analog reference voltage 12 ICDREF Input Carrier detect reference voltage 13 OCBIAS Output Comparator bias current 14 TEST10 Input Connect to VSS 15 VDDA Power Analog supply voltage 16 IRXA Input FSK modulated HART receive signal from 4-20mA loop interface circuit 17 ORXAF Output Analog receive filter output 18 IRXAC Input Analog receive comparator input 19 OXTL Output Crystal oscillator output 20 IXTL Input Crystal oscillator input 21 VSS Ground Ground 22 VDD Power Digital supply voltage 23 INRTS Input Request to send 24 ITXD Input Input transmit date, transmitted HART data stream from UART 25 TEST11 No connect 26 ORXD Output Received demodulated HART data to UART 27 OCD Output Carrier detect output 28 TEST12 No connect Rev. 3 | Page 2 of 13 | www.onsemi.com A5191HRT Table 2: Pin Out Summary 32-Pin LQFP, A5191HRTl/Lg (12197-503/507) Pin No. Signal Name Type Pin Description 1 TEST5 Input Connect to VSS 2 INRESET Input Reset all logic when low, connect to VDD for normal operation 3 TEST7 Input Connect to VSS 4 TEST8 Input Connect to VSS 5 TEST9 Input Connect to VSS 6 VSS Ground Digital ground 7 OTXA Output Output transmit analog, FSK modulated HART transmit signal to 4-20mA loop interface circuit 8 IAREF Input Analog reference voltage 9 ICDREF Input Carrier detect reference voltage 10 OCBIAS Output Comparator bias current 11 TEST10 Input Connect to VSS 12 VSSA Ground Analog ground 13 VDDA Power Analog supply voltage 14 IRXA Input FS modulated HART receive signal from 4-20mA loop interface circuit 15 ORXAF Output Analog receive filter input 16 IRXAC Input Analog receive comparator input 17 OXTL Output Crystal oscillator output 18 IXTL Input Crystal oscillator input 19 VSSA Ground Analog ground 20 VSS Ground Digital ground 21 VDD Power Digital supply voltage 22 INRTS Input Request to send 23 ITXD Input Input transmit data, transmit HART data stream from UART 24 TEST11 No connect 25 ORXD Output Received demodulated HART data to UART 26 OCD Output Carrier detect output 27 TEST12 No connect 28 TEST1 Input Connect to VSS 29 TEST2 No connect 30 VDD Power Digital supply voltage 31 TEST3 No connect 32 TEST4 No connect 3.0 Pin Descriptions Table 3: Pin Descriptions Symbol Pin Name Analog reference voltage IAREF ICDREF Carrier detect reference voltage INRESET Reset digital logic INRTS Request to send IRXA IRXAC ITXD Analog receive input Analog receive comparator input Digital transmit input (CMOS) IXTL Oscillator input OCBIAS Comparator bias current Description Analog input sets the dc operating point of the operational amplifiers and comparators and is usually selected to split the dc potential between VDD and VSS. See Table 5. Analog input controls at which level the carrier detect (OCD) becomes active. This is determined by the dc voltage difference between ICDREF and IAREF. Selecting ICDREF - IAREF equal to 0.08 VDC will set the carrier detect to a nominal 100 mVp-p When at logic low (VSS) this input holds all the digital logic in reset. During normal operation INRESET should be at VDD. INRESET should be held low for a minimum of 10nS after VDD = 2.5V as shown in Table 3. Active-low input selects the operation of the modulator. OTXA is enabled when this signal is low. This signal must be held high during power-up. Input accepts the 1200/2200Hz signals from the external filter. Positive input of the carrier detect comparator and the receiver filter comparator. Input to the modulator accepts digital data in NRZ form. When ITXD is low, the modulator output frequency is 2200Hz. When ITXD is high, the modulator output frequency is 1200Hz. Input to the internal oscillator must be connected to a parallel mode 460.8kHz ceramic resonator when using the internal oscillator or grounded when using an external 460.8kHz clock signal. The current through this output controls the operating parameters of the internal operational amplifiers and comparators. For normal operation, OCBIAS current is set to 2.54A. Rev. 3 | Page 3 of 13 | www.onsemi.com A5191HRT OCD Carrier detect output ORXAF ORXD Analog receive filter output Digital receive output (CMOS) OTXA Analog transmit output OXTL Oscillator output TEST(12:1) VDD VDDA VSS VSSA Factory test Digital power Analog supply voltage Ground Analog ground Output goes high when a valid input is recognized on IRXA. If the received signal is greater than the threshold specified on ICDREF for four cycles of the IRXA signal, the valid input is recognized. Signal is the square wave output of the receiver high-pass filter. Signal outputs the digital receive data. When the received signal (IRXA) is 1200Hz, ORXD outputs logic high. When the received signal (IRXA) is 2200Hz, ORXD outputs logic low. ORXD is qualified internally with OCD. Output provides the trapezoidal signal controlled by ITXD. When ITXD is low, the output frequency is 2200Hz. When ITXD is high, the output frequency is 1200Hz. This output is active when INRTS is low and 0.5 VDC when INRTS is high. Output from the internal oscillator must be connected to an external 460.8kHz clock signal or to a parallel mode 460.8kHz ceramic resonator when using the internal oscillator. Factory test pins; for normal operation, tie these signals as per Table 1 and Table 2 Power for the digital modem circuitry Power for the analog modem circuitry Analog and digital ground Figure 3: Reset Timing Note: This signal is also present on the LSI 20C15. It is labeled as Test6. The 20C15 data sheet mentions the reset function of this pin but does not emphasize its use to reset the chip. Reliable operation of the modem requires a hardware reset as shown in Figure 3. This is true for the AMIS 12197-503 and 12197-504 as well as the LSI 20C15. 4.0 Functional Description The A5191HRT is a functional equivalent of the SYM20C15 HART Modem. It contains a transmit data modulator and signal shaper, carrier detect circuitry, analog receiver and demodulator circuitry and an oscillator, as shown in Figure 4. Rev. 3 | Page 4 of 13 | www.onsemi.com A5191HRT The internal HART modem modulates the transmit-signal and demodulates the receive signal. The transmit-signal shaper enables the A5191HRT to transmit a HART compliant signal. The carrier is detected by comparing the receiver filter output with the difference between two external voltage references. The analog receive circuitry band-pass filters the received signal for input to the modem and the carrier detect circuitry. The oscillator provides the modem with a stable time base using either a simple external resonator or an external clock source. Figure 4: A5191HRT Block Diagram 4.1 A5191HRT Logic The modem consists of a modulator and demodulator. The modem uses shift frequencies of nominally 1200Hz (for a 1) and 220Hz (for a 0). The bit rate is 1200 bits/second. 4.1.1. Modulator The modulator accepts digital data in NRZ form at the ITXD input and generates the FSK modulated signal at the OTXA output. INRTS must be a logic low for the modulator to be active. 4.1.2. Demodulator The demodulator accepts an FSK signal at the IRXA input and reproduces the original modulating signal at the ORXD output. The nominal bit rate is 1200 bits per second. Figure 5 illustrates the demodulation process. Figure 5: Demodulator Signal Timing The output of the demodulator is qualified with the carrier detect signal (OCD), therefore, only IRXA signals large enough to be detected (100mVp-p typically) by the carrier detect circuit produce received serial data at ORXD. Maximum demodulator jitter is 12 percent of one bit given input frequencies within HART specifications, a clock frequency of 460.8kHz (±1.0 percent) and zero input (IRXA) asymmetry. Rev. 3 | Page 5 of 13 | www.onsemi.com A5191HRT 4.2 Transmit-Signal Shaper The transmit-signal shaper generates a HART compliant FSK modulated signal at OTXA. Figure 6 and Figure 7 show the transmitsignal forms of the A5191HRT. For IAREF = 1.235 VDC, OTXA will have a voltage swing from approximately 0.25 to 0.75 VDC. Figure 6: OTXA Waveform (1200Hz) Figure 7: OTXA Waveform (2200Hz) 4.3 Carrier Detect Circuitry The carrier detect comparator shown in Figure 8 generates logic low output if the IRXAC voltage is below ICDREF. The comparator output is fed into a carrier detect block (see Figure 4). The carrier detect block drives the carrier detect output pin OCD high if INRTS is high and four consecutive pulses out of the comparator have arrived. OCD stays high as long as INRTS is high and the next comparator pulse is received in less than 2.5ms. Once OCD goes inactive, it takes four consecutive pulses out of the comparator to Rev. 3 | Page 6 of 13 | www.onsemi.com A5191HRT assert OCD again. Four consecutive pulses amount to 3.33ms when the received signal is 1200Hz and to 1.82ms when the received signal is 2200HZ. 4.4 Analog Receiver Circuitry 4.4.1. Voltage References The A5191HRT requires two voltage references, IAREF and ICDREF. IAREF sets the dc operating point of the internal operational amplifiers and comparators. A 1.235 VDC reference (Analog Devices AD589) is suitable as IAREF. The level at which OCD (carrier detect) becomes active is determined by the dc voltage difference (ICDREF - IAREF). Selecting a voltage difference of 0.08 VDC will set the carrier detect to a nominal 100 mVp-p. 4.4.2. Bias Current Resistor The A5191HRT requires a bias current resistor to be connected between OCBIAS and VSS. The bias current controls the operating parameters of the internal operational amplifiers and comparators. The value of the bias current resistor is determined by the reference voltage IAREF and the following formula: The recommended bias current resistor is 500KW when IAREF is equal to 1.235 VDC. In Figure 8 all external capacitor values have a tolerance of ±5 percent and the resistors have a tolerance of ±1 percent, except the 3MW which has a tolerance of ±5 percent. External to the A5191HRT, the filter exhibits a three-pole, high-pass filter at 624Hz and a one-pole, low-pass filter at 2500Hz. Internally, the A5191HRT has a high-pass pole at 35Hz and a low-pass pole at 90kHz. The lowpass pole can vary as much as ±30 percent. The input impedance of the entire filter is greater than 150MW at frequencies below 50kHz. Figure 8: Receive Filter Schematic 4.5 Oscillator The A5191HRT requires a 460.8kHz clock signal on OXTL. This can be provided by an external clock or external components may be connected to the A5191HRT internal oscillator. Rev. 3 | Page 7 of 13 | www.onsemi.com A5191HRT 4.5.1. Internal Oscillator Option The oscillator cell will function with either a 460.8kHz crystal or ceramic resonator. A parallel resonant ceramic resonator can be connected between OXTL and IXTL. Figure 9 illustrates the crystal option for clock generation using a 460.8kHz (±I percent tolerance) parallel resonant crystal and two tuning capacitors. The actual values of the capacitors may depend on the recommendations of the manufacturer of the resonator. Typically, capacitors in the range of 100pF to 470pF are used. 4.5.2. External Clock Option It may be desirable to use an external 460.8kHz clock as shown in Figure 10 rather than the internal oscillator because of the high cost and low availability of ceramic resonators. In addition, the A5191HRT consumes less current when an external clock is used. Minimum current consumption occurs with the clock connected to OXTL and IXTL connected to VSS. Figure 9: Crystal Oscillator Figure 10: Oscillator with External Clock Rev. 3 | Page 8 of 13 | www.onsemi.com A5191HRT 5.0 Ordering Information The A5191HRT is available in a 28-pin plastic leaded chip carrier (PLCC) and 32-pin low-profile quad flat pack (LQFP). Use the following part number when ordering. Contact your local sales representative for more information: www.onsemi.com. Part Number A5191HRTLG-XTD A5191HRTLG-XTP A5191HRTPG-XTD A5191HRTPG-XTP Package 32-pin LQFP Green/RoHS compliant 32-pin LQFP Green/RoHS compliant 28-pin PLCC Green/RoHS compliant 28-pin PLCC Green/RoHS compliant Shipping Configuration Tube/Tray Temperature Range -40°C to +85°C (Industrial) Tape & Reel -40°C to +85°C (Industrial) Tube/Tray -40°C to +85°C (Industrial) Tape & Reel -40°C to +85°C (Industrial) 6.0 Electrical Specifications Table 4: Absolute Maximums Symbol Parameter Min. Max. Units TA Ambient -40 +85 °C TS Storage temperature -55 150 °C VDD Supply voltage -0.3 6.0 V VIN, VOUT DC input, output -0.3 VDD + 0.3 V TL Re-flow solder profile Per IPC/JEDEC J-STD-020C °C Cautions: 1. CMOS devices are damaged by high-energy electrostatic discharge. Devices must be stored in conductive foam or with all pins shunted. Precautions should be taken to avoid application of voltages higher than the maximum rating. Stresses above absolute maximum ratings may result in damage to the device. 2. Remove power before insertion or removal of this device. Table 5: DC Characteristics VDD = 3.0V to 5.5V, VSS = 0V TA = -40°C to +85°C Symbol Parameter VIL Input voltage, low VIH Input voltage VOL Output voltage, low (IOL = 0.67mA) VOH Output voltage, high (IOH = -0.67mA) Input capacitance Analog input CIN IRXA Digital input IIL/IH Input leakage current IOLL Output leakage current VDD 3.0 – 5.5 3.0 – 5.5 3.0 – 5.5 3.0 – 5.5 Min. Typ. Max. 0.3 * VDD 0.7 * VDD 0.4 2.4 2.9 25 3.5 nA μA 330 μA 300 1.2 1.235 V IAREF Analog reference 2.5 ICDREF* Carrier detect reference (IAREF – 0.08V) 1.15 V OCBIAS Comparator bias current (RBIAS = 500 kΩ, IAREF = 1.235V) 2.5 μA *The HART specification requires carrier detect (OCD) to be active between 80 and 120 mVp-p. Setting ICDREF at IAREF - 0.08 VDC will set the carrier detect to a nominal 100 mVp-p. IDO Power supply current (RBIAS = 500kΩ, IAREF = 1.235V) 3.3 5.0 3.3 5.0 ± 500 ± 10 450 600 2.6 Units V V V V pF Rev. 3 | Page 9 of 13 | www.onsemi.com A5191HRT Table 6: AC Characteristics VDD = 3.0V to 5.5V, VSS = 0V, TA = -40°C to +85°C Pin Name Description Min. Typ. Max. Receive analog input ±150 Leakage current IRXA 1210 1200 1190 Frequency – mark (logic 1) 2220 2200 2180 Frequency – space (logic 0) Output of the high-pass filter Slew rate 0.025 ORXAF Gain bandwidth (GBW) 150 Voltage range 0.15 VDD – 0.15 Carrier detect and receive filter input IRXAC Leakage current ±500 Modulator output Frequency – mark (logic 1) Frequency – mark (logic 0) 1196.9 OTXA Amplitude (IAREF 1.235V) 2194.3 Slope 500 Loading (IAREF = 1.235V) 30 2.79 Receive digital output ORXD Rise/fall time 20 Carrier detect output OCD Rise/fall time 20 The modular output frequencies are proportional to the input clock frequency (460.8kHz). Table 7: Modem Characteristics VDD = 3.0V to 5.5V, VSS = 0V, TA = -40°C to +85°C Parameter Demodulator jitter Conditions 1. Input frequencies at 1200Hz ±10Hz, 2200Hz ± 20Hz 2. Clock frequency of 460.8kHz ± 0.1% 3. Input (HLXA) asymmetry, 0 Table 8: Ceramic Resonator - External Clock Specifications VDD = 3.0V to 5.5V, VSS = 0V, TA = -40°C to +85°C Parameter Min. Typ. Max. Resonator Tolerance 1.0 Frequency 460.8 External Clock frequency 456.2 460.8 Duty cycle 40 50 465.4 Amplitude VOH - VOL 60 Min. Typ. Units nA Hz Hz V/μs kHz V/μs nA Hz Hz mVDD mV/μs kΩ ns ns Max. Units 12 % of 1 bit Units % kHz kHz % V Rev. 3 | Page 10 of 13 | www.onsemi.com A5191HRT 7.0 Mechanical Specifications Symbol A A1 D D1 D2 D3 E E1 E2 E3 e Min. .165 .099 .485 .450 .390 .485 .450 .390 Nom. .172 .101 .490 .452 .420 .300 REF .490 .452 .420 .300 REF .050 BSC Max. .180 .110 .495 .495 .430 .495 .455 .430 Figure 11: 28 Lead PLCC Rev. 3 | Page 11 of 13 | www.onsemi.com A5191HRT Symbol A A1 A2 D d/2 D1 E E/2 E1 L e b c ccc ddd Min. 0.05 1.35 0.45 0.30 0.09 - Nom. 0.10 1.40 9.00 BSC 4.50 BSC 7.00 BSC 9.00 BSC 4.50 BSC 7.00 BSC 0.60 0.80 BSC 0.37 - Max. 1.60 0.15 1.45 0.75 0.45 0.20 0.10 0.20 Figure 12: 32 Lead LQFP Rev. 3 | Page 12 of 13 | www.onsemi.com A5191HRT 8.0 Revision History Revision 2 3 Date March 2005 May 2008 Modification Update to new ON Semiconductor template 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. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part. SCILLC is an Equal Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner. PUBLICATION ORDERING INFORMATION LITERATURE FULFILLMENT: Literature Distribution Center for ON Semiconductor P.O. Box 5163, Denver, Colorado 80217 USA Phone: 303-675-2175 or 800-344-3860 Toll Free USA/Canada Fax: 303-675-2176 or 800-344-3867 Toll Free USA/Canada Email: [email protected] N. American Technical Support: 800-282-9855 Toll Free USA/Canada Europe, Middle East and Africa Technical Support: Phone: 421 33 790 2910 Japan Customer Focus Center Phone: 81-3-5773-3850 Rev. 3 | Page 13 of 13 | www.onsemi.com ON Semiconductor Website: www.onsemi.com Order Literature: http://www.onsemi.com/orderlit For additional information, please contact your local Sales Representative