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| T6B70BF TOSHIBA CMOS Digital Integrated Circuit Silicon Monolithic T6B70BF Interface IC for Water Heater The T6B70BF incorporates two-channel 4-bit DA converter, a pseudo sine wave generator and an external analog signal detection/non-detection circuit. It is designed to be used mainly for communication between water heater and control unit. Features * * * * On-chip two-channel 4-bit DA converter (opposite polarities) On-chip pseudo sine wave generator (external clock/16) On-chip external analog signal detection/non-detection circuit On-chip two-channel analog switch Weight: 0.16 g (typ.) Block Diagram OSCIN 1 OSCOUT 2 FOUT 3 SCTL Divide-by16 unit Pseudo sine wave generator 0C 180C 4-bit DA converter 4-bit DA converter 13 SOUT+ 12 SOUT- 16 VDD Waveform initialization block 4 Modulation control circuit Zero-cross waveform shaping circuit Amplifier input circuit SW1IN 14 SW1OUT 15 7 AMPIN 6 AMPOUT Cycle measurement counter SW2IN 11 SW2OUT 10 RESET Analog signal detection/non-detection Reset circuit Output buffer 8 VSS 9 DOUT 5 1 2003-03-13 T6B70BF Pin Assignment OSCIN OSCOUT FOUT SCTL RESET 1 2 3 4 T6B70BF 5 6 7 8 16 15 14 13 12 11 10 9 VDD SW1OUT SW1IN SOUT+ SOUT- SW2IN SW2OUT DOUT AMPOUT AMPIN VSS Pin Function No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 Symbol OSCIN OSCOUT FOUT SCTL RESET Input/Output Input Output Output Input Input Output Input Output Output Input Output Output Input Output Function Pins connected to oscillation Pins connected to oscillation Output pin for oscillation waveform shaping circuit Modulation control signal input pin Reset signal input pin Amplifier signal output pin Amplifier signal input pin Device GND pin (0 V) Output pin for amplifier input signal detector Output pin on analog SW2 side Input pin on analog SW2 side Pseudo sine wave (opposite polarity of SOUT+ output) output pin Pseudo sine wave output pin Input pin on analog SW1 side Output pin on analog SW1 side Device power supply pin (+5 V) AMPOUT AMPIN VSS DOUT SW2OUT SW2IN SOUT- SOUT+ SW1IN SW1OUT VDD 2 2003-03-13 T6B70BF Function Description (1) Pseudo sine wave generator and 4-bit DA converters (sending block) Pseudo sine wave signal with Fosc/16 frequency is driven out from pseudo sine wave output pin (SOUT+ and SOUT-). The outputs of pins SOUT+ and SOUT- have the opposite polarities. The block of pseudo sine wave generator and 4-bit DA converter (the side of SOUT+ pin) are shown below. SOUT+ pin MSB Pseudo sine wave generator R R R SOUT+ R R R R LSB R R SOUT- FOSC RST VSS The data of pseudo sine wave generator is driven out in the following sequence. 0 1 3 6 9 C E F F E C 9 6 3 1 0 (in hexadecimal) FF E C E C 2R 9 R R 9 6 3 01 FSIN 250 kHz @FOSC = 4 MHz 6 3 10 Thus, the pseudo sine waveform of positive-going and negative-going outputs is like a staircase at no load. An analog switch is incorporated so that the driver output buffer is connected to the transmission line only when transmission is performed. However, an emitter follower circuit is externally connected to the driver output buffer. The phase difference between positive-going and negative-going outputs is within 180 5. (pseudo sine wave output phase fluctuation) 3 2003-03-13 T6B70BF (2) Amplifier input circuit and signal detection/non-detection circuit (receiving block) The modulation signal input block incorporates two level comparators having a high and a low threshold values to detect the external sine wave signal with amplitude higher than the specified threshold. Thus, it avoids signals with amplitude lower than the specified threshold (e.g., noise signals) being detected erroneously. The detection frequency range (frequency window) is determined by the divider ratio 1/18 to 1/14 of Fosc. In detection/non-detection determined condition, when the signals within the specified frequency range are detected (or not detected) sequentially, signals are controlled using the majority rule. The time which detection/non-detection is determined takes 9 to 15 waves to pass when one wave is referenced to Fosc/16 frequency. VDD R1 APU VDD Reference voltage VH RESET High comparator VA R Q Cycle measurement counter APD R3 7 AMPIN pin Reference voltage VL VBIAS Low comparator VB S Q RESET Analog signal detection 9 /nondetection DOUT pin circuit R4 R2 VSS VSS VDD 6 AMPOUT pin AMPIN input sine waveform VH Input sensitivity VPP VL Detect reception Not detect reception Not detect reception Not detect reception AMPOUT output timing (when RESET is Low) VH VBIAS AMPOUT Truth Table VA VBIAS > VH VH > VBIAS > VL L H H VB H H L AMPOUT L Hold H VL Held at High Held at Low VBIAS < VL AMPOUT VBIAS < VL VBIAS > VH VH > VBIAS > VL VH > VBIAS > VL 4 2003-03-13 T6B70BF (3) Function description and timing chart of the sending block When modulation control input ( SCTL ) is in High-level, pseudo sine wave output is held at 0 of the phase angle of pseudo sine wave. When modulation control input changes from High-level to Low-level, the pseudo sine wave output (SOUT+) starts from -90 (SOUT- starts from +90). In this case, the time which takes to turn ON is as follows. td (ON) < 500 ns When modulation control input changes from Low-level to High-level, the phase angle is forcibly held at 0, regardless of the phase of the pseudo sine wave output. (the pseudo sine wave output is stopped). In this case, the time which takes to turn OFF is as follows. td (OFF) < 1 s SCTL td (ON) SOUT+ pseudo sine wave output (SOUT- output pin has the opposite polarity) td (OFF) (4) Function description and timing chart of the receiving block When it is ready to receive amplifier input signal, the time T (DET) which takes to change from High to Low at DOUT pin is within the time which 9 to 15 waves to pass. In this case, one wave is referenced to 16 Fosc clocks. The time width is determined by the internal clock and amplifier input signal. The timings of the internal clock and internal detection signal in the majority logic circuit are synchronous with each other. When input signals with the cycle, which is within the range specified by the frequency window, are detected (or not detected) sequentially, this rule is valid (the majority rule). Amplifier input T (DET) T (DET) DOUT Note 1: Any communication protocol is used, however, it takes 15 carrier waves to pass when the signal changes its state. 5 2003-03-13 T6B70BF Timing Chart (SOUT+ = SW1IN, SW1OUT, SOUT- = SW2IN, SW2OUT) VDD RESET OSCIN (4 MHz) FOUT AMPIN (250 kHz) VPP AMPOUT High-z SCTL When sending td (ON) FSIN td (OFF) SOUT+ VOPP SOUT- DOUT TDET When receiving TDET SW1IN SW1OUT High-z High-z SW2IN SW2OUT High-z High-z 6 2003-03-13 T6B70BF Maximum Ratings (Ta = 25C 1.5C) Characteristics Power supply voltage Input voltage Input peak current Operating temperature Storage temperature Power dissipation Symbol VDD VI IIK Topr Tstg PD (Note 1) Rating -0.3 to 6.0 -0.3 to VDD + 0.3 -20 to 20 -20 to 80 -55 to 125 0.54 Unit V V mA C C W Note 1: Decreases approximately 4.35 mW per 1C. Electrical Characteristics Characteristics VDD pin (pin 16) Operating voltage Current consumption (unless otherwise specified, VDD = 5.0 V, VSS = 0 V, FOSC = 4 MHz and Ta = -20 to 80C) Symbol Test Circuit 1 Test Condition Min Typ. Max Unit VDD IDD FOSC VIHOSC VILOSC IIHROSC IILROSC VOHOSC VOLOSC No load, Fosc = 4 MHz 4.5 5.0 5.5 10 V mA OSCIN pin (pin 1) and OSCOUT pin (pin 2) Oscillation frequency High level Input voltage Low level Input current High level Low level High level Output voltage Low level RESET pin (pin 5) 2 3 3 4 4 3 4 VIN = 5 V, Ta = 25C VIN = 0 V, Ta = 25C IOH = -0.1 mA IOL = +0.1 mA 1 0.7 VDD VSS 3.2 -3.2 VDD - 1.0 VSS 4 6.58 -6.58 10 VDD 0.3 VDD 13.2 -13.2 VDD VSS + 0.6 MHz V A V Low to High input switching level High to Low input switching level High-level input current Pull-up resistance 1 Pull-up resistance 2 SCTL pin (pin 4) VIHRST VILRST IIHRST IILRRST1 IILRRST2 5 5 6 7 7 VIN = VDD 0.65 VDD VSS -10 9 6.3 15 VDD 0.35 VDD 10 21 27.3 V V A k k VIN = VSS, Ta = 25 VIN = VSS, Ta = -20 to 80 Low to High input switching level High to Low input switching level Input current FOUT pin (pin 3) High level Output voltage Low level High level Low level VIHSCTL VILSCTL IIHSCTL IILSCTL 8 8 9 9 VIN = VDD VIN = VDD 0.65 VDD VSS -1 -1 VDD 0.35 VDD 1 1 V V A VOHFOUT VOLFOUT 10 11 IOH = -1.0 mA IOL = +1.0 mA VDD - 1.0 VSS VDD VSS + 0.6 V Note 2: One direction in which current flow into the IC should be + (sink) and the other direction in which current flow out from the IC should be - (drain). 7 2003-03-13 T6B70BF Characteristics DOUT pin (pin 9) Symbol Test Circuit Test Condition Min Typ. Max Unit High level Output voltage Low level VOHDOUT VOLDOUT 12 13 IOH = -1.0 mA IOL = +1.0 mA Fosc = 4 MHz, AMPIN = 250 kHz Time which takes DOUT to change from High to Low Fosc = 4 MHz, AMPIN = 250 kHz Time which takes DOUT to change from Low to High VDD - 1.0 VSS VDD VSS + 0.6 V Non-reception to reception detection time TDET1 19 40 60 s Reception to non-reception detection time AMPIN pin (pin 7) Input dynamic range Pull-up resistance 1 Pull-up resistance 2 Pull-down resistance 1 Pull-down resistance 2 Amplifier input bias voltage TDET2 19 36 56 s VAMPIN IILRAPU1 IILRAPU2 IIHRAPD1 IIHRAPD2 VBIAS 14 15 15 16 16 17 VIN = VSS, Ta = 25 VIN = VSS, Ta = -20 to 80 VIN = VDD, Ta = 25 VIN = VDD, Ta = -20 to 80 No load (design goal) No load, receivable amplitude range is 250 kHz, when sine wave signal is applied. (design goal) Fosc = 4 MHz Fosc = 4 MHz Fosc = 4 MHz VSS 11.6 7 5.9 3 1.54 19.4 9.8 1.63 VDD 27.2 38 13.7 19.2 1.71 V k k k k V Amplifier input sensitivity VPP DETON DETOFF1 DETOFF2 18 0.3 0.45 V Detection frequency range Non-detection frequency (low frequency) Non-detection frequency (high frequency) 19 19 19 236 286 266 222 kHz kHz kHz SW1IN pin (pin 14) and SW1OUT pin (pin 15) Analog switch input voltage Analog switch output voltage OFF-leak current of analog switch 1 VINASW1 VOUTASW1 IOFFASW1 20 SCTL = H, SW1IN = VDD, SW1OUT = VSS SCTL = L, SW1IN = 5 V, SW1OUT = 0 V VSS VSS -1 VDD VDD 1 V V A ON-resistance of analog switch 1 RONASW1 21 35 105 Current measure SW2IN pin (pin 11) and SW2OUT pin (pin 10) Analog switch input voltage Analog switch output voltage OFF-leak current of analog switch 2 VINASW2 VOUTASW2 IOFFASW2 20 SCTL = H, SW2IN = VDD, SW2OUT = VSS SCTL = L, SW2IN = 5 V, SW2OUT = 0 V VSS VSS -1 VDD VDD 1 V V A ON-resistance of analog switch 2 RONASW2 21 35 105 Current measure SOUT+ pin (pin 13) and SOUT- pin (pin 12) Output voltage Pseudo sine wave output frequency Pseudo sine wave output start time Pseudo sine wave output stop time Equivalent output impedance VOPP FSIN tdON tdOFF ROUTSIN 22 23 23 23 24 Maximum voltage value at no load FOSC = 4 MHz SCTL = H L SCTL = L H 0.85 VDD 2.8 250 4 VDD 500 1 5.2 V kHz ns s k No load Note: One direction in which current flow into the IC should be + (sink) and the other direction in which current flow out from the IC should be - (drain). 8 2003-03-13 T6B70BF Test Circuit (1) Current consumption 5V ICC (2) Oscillation frequency 4 MHz PG A 1 OSCIN VDD 16 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 9 1 to 10 MHz PG Monitor Fosc 5V 1 OSCIN VDD 16 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 9 (3) High-level input voltage Low-level input voltage High-level output voltage (4) High-level input current Low-level input current Low-level output voltage IIHROSC IILROSC A IOL 1 OSCIN +0.1 mA VDD 16 5V VDD 16 1 OSCIN VIHOSC VOHOSC VILOSC 2 OSCOUT SW1OUT 15 -0.1 mA IOH V 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 5V VIN 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT VOLOUT V 9 9 (5) Low to High input switching level High to Low input switching level 5V 1 OSCIN VDD 16 (6) High-level input current 4 MHz PG 5V 1 OSCIN VDD 16 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL VIHRST VILRST 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 2 OSCOUT SW1OUT 15 3 FOUT Monitor Monitor VIN IIHRST 4 SCTL A 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 9 9 9 2003-03-13 T6B70BF (7) Pull-up resistance 1 Pull-up resistance 2 5V 1 OSCIN VDD 16 (8) Low to High input switching level High to Low input switching level 5V 1 OSCIN VDD 16 4 MHz PG 2 OSCOUT SW1OUT 15 IILRRST1 3 FOUT IILRRST2 4 SCTL A 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 9 2 OSCOUT SW1OUT 15 3 FOUT VIHSCTL VILSCTL 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT Monitor Monitor 9 (9) High-level input current Low-level input current 5V 1 OSCIN VDD 16 (10) High-level output voltage 5V 1 OSCIN VDD 16 -1.0 mA OSCOUT SW1OUT 15 IIHSCTL 2 IILSCTL 3 FOUT SW1IN 14 A VIN 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 2 OSCOUT SW1OUT 15 3 FOUT IOH VOHFOUT V 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 9 9 (11) Low-level output voltage 5V +1.0 mA 1 OSCIN IOL VDD 16 (12) High-level output voltage 5V 1 OSCIN VDD 16 4 MHz PG 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 -1.0 mA DOUT VOLFOUT V 9 9 VOHDOUT V 10 2003-03-13 IOH T6B70BF (13) Low-level output voltage 5V 1 OSCIN VDD 16 (14) Input dynamic range 5V 1 OSCIN VDD 16 4 MHz PG 4 MHz PG 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 +1.0 mA SW2IN 11 SW2OUT 10 DOUT 9 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET Monitor IOL VAMPIN 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 9 VOLDOUT V (15) Pull-up resistance 1 Pull-up resistance 2 5V 1 OSCIN VDD 16 (16) Pull-down resistance 1 Pull-down resistance 2 5V 1 OSCIN VDD 16 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL IILRAPU1 5 RESET IILRAPU2 6 AMPOUT A 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL IIHRAPD1 5 RESET IIHRAPD2 6 AMPOUT A VIN 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 9 9 (17) Amplifier input bias voltage 5V 1 OSCIN VDD 16 (18) Amplifier input sensitivity 5V 1 OSCIN VDD 16 4 MHz PG 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN VBIAS V 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET Monitor 250 kHz Vp-p sine wave 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 9 9 11 2003-03-13 T6B70BF (19) Detection frequency range Non-detection frequency (low frequency) Non-detection frequency (high frequency) Non-reception to reception detection time Reception to non-reception detection time 5V 1 OSCIN VDD 16 1 OSCIN VDD 16 IOFFASW1 5.0 V V VOPP V VOPP 5.0 V 5.0 V 5.0 V A (20) OFF-leak current of analog switch 1 OFF-leak current of analog switch 2 4 MHz PG 5V 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL DETON DETOFF1 DETOFF2 200 to 300 kHz PG 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 9 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN Monitor TDET1 TDET2 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 IOFFASW2 SW2IN 11 SW2OUT 10 DOUT A 9 (21) ON-resistance of analog switch 1 ON-resistance of analog switch 2 5V 1 OSCIN VDD 16 RONASW1 5.0 V A (22) Output voltage 4 MHz PG 5V 1 OSCIN VDD 16 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT SOUT- 12 RONASW2 5.0 V SW2IN 11 SW2OUT 10 DOUT A 9 9 (23) Pseudo sine wave output frequency Pseudo sine wave output start time Pseudo sine wave output stop time 5V 1 OSCIN VDD 16 (24) Equivalent output impedance 4 MHz PG 4 MHz PG 5V 1 OSCIN VDD 16 2 OSCOUT SW1OUT 15 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT 2 OSCOUT SW1OUT 15 FSIN Monitor DEGSOUT Monitor tdON tdOFF 3 FOUT 4 SCTL 5 RESET 6 AMPOUT 7 AMPIN 8 VSS SW1IN 14 SOUT+ 13 SOUT- 12 SW2IN 11 SW2OUT 10 DOUT A ROUTSIN A ROUTSIN 9 9 12 2003-03-13 T6B70BF Markings LOT CODE T6B70BF 13 2003-03-13 T6B70BF Package Dimensions Weight: 0.16 g (typ.) 14 2003-03-13 T6B70BF RESTRICTIONS ON PRODUCT USE 000707EBA * TOSHIBA is continually working to improve the quality and reliability of its products. Nevertheless, semiconductor devices in general can malfunction or fail due to their inherent electrical sensitivity and vulnerability to physical stress. It is the responsibility of the buyer, when utilizing TOSHIBA products, to comply with the standards of safety in making a safe design for the entire system, and to avoid situations in which a malfunction or failure of such TOSHIBA products could cause loss of human life, bodily injury or damage to property. In developing your designs, please ensure that TOSHIBA products are used within specified operating ranges as set forth in the most recent TOSHIBA products specifications. Also, please keep in mind the precautions and conditions set forth in the "Handling Guide for Semiconductor Devices," or "TOSHIBA Semiconductor Reliability Handbook" etc.. * The TOSHIBA products listed in this document are intended for usage in general electronics applications (computer, personal equipment, office equipment, measuring equipment, industrial robotics, domestic appliances, etc.). These TOSHIBA products are neither intended nor warranted for usage in equipment that requires extraordinarily high quality and/or reliability or a malfunction or failure of which may cause loss of human life or bodily injury ("Unintended Usage"). Unintended Usage include atomic energy control instruments, airplane or spaceship instruments, transportation instruments, traffic signal instruments, combustion control instruments, medical instruments, all types of safety devices, etc.. Unintended Usage of TOSHIBA products listed in this document shall be made at the customer's own risk. * The products described in this document are subject to the foreign exchange and foreign trade laws. * The information contained herein is presented only as a guide for the applications of our products. No responsibility is assumed by TOSHIBA CORPORATION for any infringements of intellectual property or other rights of the third parties which may result from its use. No license is granted by implication or otherwise under any intellectual property or other rights of TOSHIBA CORPORATION or others. * The information contained herein is subject to change without notice. 15 2003-03-13 |
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