Dick Smith Electronics catalogue data.pdf
18
0
0
Full text
(2) 7770 Catalogue Pg 388 pc. 10/21/04. 12:55 PM. Page 388. Data RESISTOR COLOUR CODE. 4—Band code. 5—Band code. 388. see the full range at www.dse.com.au. 47k‰. 51k‰.
(3) 7770 Catalogue Pg 389 pc. 10/21/04. 2:50 PM. Page 389. TEMPERATURE CHARACTERISTICS. CAPACITORS Capacitors may be marked to show their value, voltage rating, accuracy, temperature stability and other information. Most capacitors are not marked with all of these, however, the value and voltage rating are usually given. Identification can be difficult because of the variety of systems in use.. UNITS The unit of capacitance is the Farad, but this unit is too large in practice. Commonly used smaller units are the microfarad (abbreviated uF), nanofarad (nF) and picofarad (pF). The section on decimal multipliers (page 274) shows the relationship between these. Some capacitance values are commonly expressed by only one unit while others can be expressed under two or more units, e.g. 1uF would rarely be called 1000nF and never 1,000,000 pF, even though these are equivalent. However, 0.0047uF is often expressed as 4.7nF, or as 4700pF.. VALUE Larger capacitors are marked in microfarads and indicate this by the abbreviations ‘uF’, ‘u’ or even the obsolete ‘MFD’. Smaller capacitors are marked in nanofarads or picofarads and may abbreviate the unit to ‘n’ or ‘p’. If the value contains a decimal point the ‘u’, ‘n’ or ‘p’ is sometimes put in place of the decimal point. Therefore a 4.7pF capacitor can be marked as 4p7. If no unit is given, a judgement, based on the capacitor’s physical size, must be made to determine which unit is intended. For example, a small ceramic capacitor marked ‘4.7’ is probably 4.7 pF, whereas a large plastic capacitor marked ‘4.7’ is more likely to be 4.7uF. If the value is in nF then this is invariably shown. Another marking system uses 3 numeric digits to indicate the value in picofarads. The first two digits represent the first two digits of the value and the third digit is the multiplier or number of zeroes. For example, a capacitor marked 104 would be read as 1, 0, 0000. This would be formatted as 100,000 pF and would commonly be known as 100nF or 0.1uF. Likewise a capacitor marked 472 would be 4700pF, also known as 4.7nF or .0047uF. A similar system represents these 3 digits using colours taken from the resistor code, instead of numbers.. SOME COMMON VALUES AND THEIR POSSIBLE MARKINGS: MICROFARADS NANOFARADS 0.0001uF* 0.1n* 0.00022uF* 0.22n (n22) 0.001uF 1n (1n0) 0.0033uF 3.3n (3n3) 0.01uF 10n 0.047uF 47n 0.1uF (u1) 100n 0.82uF (u82) 820n 1.0uF (1u0) 1000n* * Not normally expressed in this form.. PICOFARADS 100pF 220pF 1,000pF 3,300pF 10,000pF* 47,000pF* 100,000pF* 820,000pF* 1,000,000pF*. EIA CODE 101 221 102 332 103 473 104 824 105. VOLTAGE RATING Voltage rating is usually marked and is often identified by the symbol ‘V’. Most electrolytic capacitors clearly indicate their voltage rating. Polyester capacitors usually show the voltage rating but often omit the ‘V’ symbol. Small ceramic capacitors often show no voltage rating. If the capacitance and voltage rating are both marked, a unit is also marked for at least one of the quantities so that the two cannot be confused.. TOLERANCE Tolerance indicates how close a capacitor’s actual value is likely to be to its marked value. A tolerance can be marked numerically, as a code consisting of a single letter, or, on colour-coded capacitors, as a fourth coloured band. The code letter is usually placed immediately after the value. Commonly used tolerance codes are: CODE A C D E F G J K. COLOUR – red green white brown red green white. TOL +20-10 (2) +/-0.25pF (1) +/-0.5pF (1) +/-1.0pF (1) +/-1% +/-2% +/-5% +/-10% Z. CODE L M N P Q (2) S W W (2) grey. COLOUR – black – – – – – +80 -20. TOL +/-15% +/-20% +/-30% +100 -0 +30 -10 +50 -20 +50 -10 +40 -20. (1) used on capacitors <=10pF (2) used on electrolytic capacitors. POLARITY Polarity sensitive capacitors, such as electrolytics, are usually marked with a ‘+’ or ‘-’ symbol adjacent to one lead to indicate polarity. Thomson brand tantalum capacitors may have a triangular logo to indicate the positive lead, instead of the ‘+’ symbol.. All real capacitors exhibit some change in value with varying temperature. Some ceramic types exhibit fairly linear changes and are useful as temperature compensating elements in AC circuits. The temperature coefficients of these types may be marked in letter codes or designated by a coloured spot. TEMPCO CODE P100 NP0 N30 N033 N075 N080 N150 N220 N330 N470 N750 N1500 N2200 P350/N1000. EIA CODE COG S1G S1G U1G U1G P2G R2G S2H T2H U2J P3K R3L SL. JIS TEMPCO CODE COLOUR red/violet C black H brown red L red P orange R yellow S green T blue U violet W orange/orange SL. PPM/°C +100 0 -30 -33 -75 -80 -150 -220 -330 -470 -750 -1500 -2200 +350 to -1000. Capacitors using the JIS code sometimes have a second letter to designate the temperature coefficient’s tolerance. LETTER G H J K L. TEMPCO TOLERANCE +/-30ppm/°C +/-60ppm/°C +/-120ppm/°C +/-250ppm/°C +/-500ppm/°C. For example, a capacitor marked ‘CH’ would have a temperature coefficient of between +60ppm/ºC and -60ppm/°C (‘C’=0, ‘H’= +/60ppm/°C). Ceramic capacitors with non-linear temperature coefficients sometimes use a 3-digit code to indicate – their operating temperature range and their stability over that range. The 1st character indicates minimum operating temperature, the 2nd, maximum temperature and the 3rd gives the stability over this temperature range. 1ST CHARACTER TEMP X Y Z. MIN TEMP °C. 2ND CHARACTER °C MAX. -55 -30 +10. 5 7. +85 +125. PUTTING IT ALL TOGETHER Knowing how the important information is likely to be marked, we can decode the markings on a capacitor and determine its value, voltage rating, tolerance and sometimes its temperature characteristic. For example, a capacitor marked 104K 63V Y5P will be 0.1uF (decoded from the 104) having a +/-10% tolerance (decoded from the K), a 63 Volt rating, an operating temperature range of -30° to + 85° (decoded from Y5) and a stability of +/-10% (P) over this range. Likewise, 6n8K63 would indicate 6.8nF (from 6n8), +/10%, (from K) and 63 Volts (from 63). 104 = = K = 63 = Y = 5 = P =. 1 0 0000 pF 100nF = 0.1 uF ± 10% Tolerance 63V -30°C +85°C ±10% Stability. FILM CAPACITOR TYPES KP KS KT MK MKC MKP MKT MKT-P MKY MKL (MKU). Ideal for use in filtering or smoothing applications in power supplies. Also used for coupling and bypassing in audio circuits and as a timing element in non critical circuits. Modern aluminium electrolytic capacitors have high reliability and low leakage. Special low leakage versions are available with leakage which rivals that of tantalum capacitors. Single ended (- end) (+ end). SOLID TANTALUM CAPACITORS Offer smaller size and lower leakage than standard aluminium electrolytics.. CERAMIC CAPACITORS Offer low cost and high capacitance in a small physical volume. There are generally two types: High stability, temperature compensating types for use in resonant circuit and filter applications. These have linear temperature characteristics, and their value is largely independent of voltage and frequency. Bypass and coupling capacitors for use in less critical applications. These are less stable, have non-linear temperature characteristics and are somewhat voltage dependent.. PAPER CAPACITORS An original construction, now rarely used. Plastic film capacitors have replaced paper capacitors in most applications.. POLYESTER CAPACITORS Low cost, good stability and available in a large range of values. These are the most widely used capacitors for general purpose applications. Greencaps and MKT type capacitors are examples of polyester (polyethylene terephthalate) film capacitors.. POLYCARBONATE CAPACITORS. 3RD CHARACTER STABILITY (%) F +/-7.5 P +/-10 R +/-15 S +/-22 T +22/-33 U +22/-56 V +22/-82 An example of this is the common ‘Z5U’ type used in bypass applications. This capacitor operates over the +10° to +85° temperature range and exhibits a stability of +22 to -56% over this temperature range.. 104K63 Y5P. CAPACITORS AND THEIR USES ALUMINIUM ELECTROLYTIC CAPACITORS. Polypropylene film/foil Polystyrene film/foil Polyester film/foil (polyethylene terephthalate PETP) Metallised plastic film (general) Metallised polycarbonate Metallised polypropylene Metallised polyester (polyethylene terephthalate, PETP) Metallised polyester/paper Metallised low-loss polypropylene Metallised lacquer (cellulose acetate). Offer low temperature coefficient and lower dielectric losses at high frequency. Most often chosen for temperature stability characteristics.. POLYSTYRENE CAPACITORS Usually chosen for applications requiring tight tolerance coupled with high stability. Predictable temperature coefficient used in conjunction with particular ferrite cores makes highly stable tuned circuits or oscillators.. POLYPROPYLENE CAPACITORS Offer very low dielectric losses and good temperature coefficient. Used in power electronics applications, e.g. mains capacitors, switching power supplies, inverters and TV deflection circuits.. INDUCTORS There are a variety of marking systems for small inductors. The value may be marked directly, with a three digit numeric code or a colour code. The tolerance may be marked directly, with a single letter, or a colour code. The 3-digit numeric code indicates the value in microhenries. The first two digits represent the first two digits of the value and the third is the multiplier, or number of zeroes. For example, the code 472 would be interpreted as 4 7 00uH, or 4.7mH. Likewise, 103 would represent 10mH. Where coloured bands are used, the system is essentially the same as that used for the resistor colour code, but with the value expressed in microhenries. An exception is that some inductors include an extra, thicker band at one end to identify milspec characteristics. Tolerance codes are usually placed after the value code. M is used to represent +/-20%, K or a silver band for +/-10%, J or a gold band for +/- 5%. Resin-dipped radial lead types are often marked with a sequence of coloured dots. The significance of these dots is shown below. 4th Dot (Tolerance) 1st Dot 2nd Dot 3rd Dot (Multiplier). see the full range at www.dse.com.au 389.
(4) 7770 Catalogue Pg 390-391 pc. 10/25/04. 11:55 AM. Page 390. Data CAPACITOR CODE AND CONVERSION CHART MICROFARAD. NANOFARAD.. PICOFARAD. EUROPEAN. EIA/MIL (USA). COLOUR BAND CODE. 0.001uF 0.0012uF 0.0015uF 0.0018uF 0.0022uF 0.0027uF 0.0033uF 0.0039uF 0.0047uF 0.0056uF 0.0068uF 0.0082uF. 1.0nF 1.2nF 1.5nF 1.8nF 2.2nF 2.7nF 3.3nF 3.9nF 4.7nF 5.6nF 6.8nF 8.2nF. 1000pF 1200pF 1500pF 1800pF 2200pF 2700pF 3300pF 3900pF 4700pF 5600pF 6800pF 8200pF. 1n0 1n2 1n5 1n8 2n2 2n7 3n3 3n9 4n7 5n6 6n8 8n2. 102 122 152 182 222 272 332 392 472 562 682 822. Brown-Black-Red Brown-Red-Red Brown-Green-Red Brown-Grey-Red Red-Red-Red Red-Violet-Red Orange-Orange-Red Orange-White-Red Yellow-Violet-Red Green-Blue-Red Blue-Grey-Red Grey-Red-Red. 0.01uF 0.012uF 0.015uF 0.018uF 0.022uF 0.027uF 0.033uF 0.039uF 0.047uF 0.056uF 0.068uF 0.082uF. 10nF 12nF 15nF 18nF 22nF 27nF 33nF 39nF 47nF 56nF 68nF 82nF. 10x103pF* 12x103pF* 15x103pF* 18x103pF* 22x103pF* 27x103pF* 33x103pF* 39x103pF* 47x103pF* 56x103pF* 68x103pF* 82x103pF*. 10n 12n 15n 18n 22n 27n 33n 39n 47n 56n 68n 82n. 103 123 153 183 223 273 333 393 473 563 683 823. Brown-Black-Orange Brown-Red-Orange Brown-Green-Orange Brown-Grey-Orange Red-Red-Orange Red-Violet-Orange Orange-Orange-Orange Orange-White-Orange Yellow-Violet-Orange Green-Blue-Orange Blue-Grey-Orange Grey-Red-Orange. 0.1uF 0.12uF 0.15uF 0.18uF 0.22uF 0.27uF 0.33uF 0.39uF 0.47uF 0.56uF 0.68uF 0.82uF. 100nF 120nF 150nF 180nF 220nF 270nF 330nF 390nF 470nF 560nF 680nF 820nF. 10x104pF* 12x104pF* 15x104pF* 18x104pF* 22x104pF* 27x104pF* 33x104pF* 39x104pF* 47x104pF* 56x104pF* 68x104pF* 82x104pF*. µ10 µ12 µ15 µ18 µ22 µ27 µ33 µ39 µ47 µ56 µ68 µ82. 104 124 154 184 224 274 334 394 474 564 684 824. Brown-Black-Yellow Brown-Red-Yellow Brown-Green-Yellow Brown-Grey-Yellow Red-Red-Yellow Red-Violet-Yellow Orange-Orange-Yellow Orange-White-Yellow Yellow-Violet-Yellow Green-Blue-Yellow Blue-Grey-Yellow Grey-Red-Yellow. Notes: *These values are not normally expressed in nanofarads (nF) or picofarads (pF). Electrolytics are usually marked in microfarads (uF) Capacitor colour code follows a similar system to that used for resistors and is expressed in picofarads. Colour Coding may vary depending on the type of capacitor, age and manufacturers preference. Most modern capacitors are marked using the European or EIA codes. 390. see the full range at www.dse.com.au.
(5) 7770 Catalogue Pg 390-391 pc. 10/25/04. 11:55 AM. Page 391. CAPACITOR CODE AND CONVERSION CHART MICROFARAD. NANOFARAD.. PICOFARAD EUROPEAN. EIA/MIL (USA). COLOUR BAND CODE. 1.0uF 1.2uF 1.5uF 1.8uF 2.2uF 2.7uF 3.3uF 3.9uF 4.7uF 5.6uF 6.8uF 8.2uF. 1000nF 1200nF 1500nF 1800nF 2200nF 2700nF 3300nF 3900nF 4700nF 5600nF 6800nF 8200nF. 10x105pF* 12x105pF* 15x105pF* 18x105pF* 22x105pF* 27x105pF* 33x105pF* 39x105pF* 47x105pF* 56x105pF* 68x105pF* 82x105pF*. 1µ0 1µ2 1µ5 1µ8 2µ2 2µ7 3µ3 3µ9 4µ7 5µ6 6µ8 8µ2. 105 125 155 185 225 275 335 395 475 565 685 825. Brown-Black-Green Brown-Red-Green Brown-Green-Green Brown-Grey-Green Red-Black-Green Red-Red-Green Orange-Orange-Green Orange-White-Green Yellow-Violet-Green Green-Blue-Green Blue-Grey-Green Grey-Red-Green. 10.0uF 15.0uF 18.0uF 22.0uF 27.0uF 33.0uF 39.0uF 47.0uF 56.0uF 68.0uF 82.0uF. 10000nF 15000nF 18000nF 22000nF 27000nF 33000nF 39000nF 47000nF 56000nF 68000nF 82000nF. 10x106pF* 15x106pF* 18x106pF* 22x106pF* 27x106pF* 33x106pF* 39x106pF* 47x106pF* 56x106pF* 68x106pF* 82x106pF*. 10µ 15µ 18µ 22µ 27µ 33µ 39µ 47µ 56µ 68µ 82µ. 106 156 186 226 276 336 396 476 566 686 826. Brown-Black-Blue Brown-Green-Blue Brown-Grey-Blue Brown-Black-Blue Red-Red-Blue Orange-Orange-Blue Orange-White-Blue Yellow-Violet-Blue Green-Blue-Blue Blue-Grey-Blue Grey-Red-Blue. 100uF 220uF. 100,000nF 220,000nF. 10x107pF* 22x107pF*. 100µ 220µ. 107 227. Brown-Black-Violet Red-Red-Violet. CAPACITOR TOLERANCES. CAPACITOR VOLTAGES. CAPACITANCE FORMULAE. Brown Red Green White Black F G J K M. (Flat Film Type, Last Band) Brown = 100 VDC Red = 250 VDC Yellow = 400 VDC Violet = 630 VDC. Parallel: CT= C1 + C2 + C3 +. = +/-1% = +/-2% = +/-5% = +/-9% or +/-10% = +/-20% = +/-1% = +/-2% = +/-5% = +/-10% = +/-20%. (Solid Tantalum, Last Band) Black = 10 VDC Brown = 1.6 VDC Red = 4.0 VDC Orange = 40 VDC Yellow = 400 VDC Green = 16 VDC Silver = 25 VDC White = 2.5 VDC Pink = 35 VDC. + Tantalum. C1 x C2 Series: CT= C1 + C2 1 CT= 1 + 1 + 1 + .. C1 C2 C3. Flat Film. Stored Charge: Q = C x E Voltage. Stored Energy: W = C x E2 2. Tolerance. Q =Charge in Coulombs C =Capacitance in Farads (F) E = Voltage (V) W= Energy in Joules (watt-seconds). Multiplier Multiplier 2nd figure 1st figure. see the full range at www.dse.com.au 391.
(6) 7770 Catalogue Pg 392 pc. 10/21/04. 2:53 PM. Page 392. Data WIRE AND COAXIAL CABLE SPECIFICATIONS Type RG-6/U RG-8/U RG-9/U RG-11/U RG-58/U RG-58A/U RG-58C/U RG-59/U RG-59B/U RG-62/U RG-62B/U RG-122/U RG-141A/U RG-142B/U RG-174/U RG-178B/U RG-179B/U RG-180B/U RG-187A/U RG-188A/U RG-196A/U RG-213/U RG-214/U RG-223/U RG-303/U RG-316/U BEL 9913. Nom. Imp Zo 75 52 51 75 53.5 50 50 73 75 93 93 50 50 50 50 50 75 95 75 50 50 50 50 50 50 50 50. Outer Dia. (mm) 6.85 10.3 10.67 10.29 4.95 4.95 4.95 6.15 6.15 6.04 6.15 4.06 4.83 4.95 2.56 1.83 2.54 3.56 2.66 2.59 1.93 10.29 10.8 5.38 4.31 2.49 10.29. Nom. Attenuation (dB/100m) 50 100 200 MHz MHz MHz 4.9 6.9 10.2 5.2 7.2 10.5 5.2 7.2 10.5 4.3 6.6 9.5 10.2 14.8 22.3 10.8 16.1 23.9 10.8 16.1 23.9 7.9 11.2 16.1 7.9 11.2 16.1 6.2 8.9 12.5 6.6 9.5 13.8 14.8 23 32.8 6.9 10.5 15.4 8.9 12.8 18.4 21.7 29.2 39.4 34.4 45.9 62.3 27.9 32.8 41.0 15.1 18.7 24.9 27.9 32.8 41 31.5 37.4 46.6 34.4 45.9 62.3 5.2 7.2 10.5 5.2 7.2 10.5 10.1 14.8 21 6.9 10.5 15.4 30.8 34.1 43.3 3.0 4.6 5.9. 400 MHz 14.4 15.4 15.4 13.8 32.8 37.7 37.7 23.3 23 17.7 20 49.9 22.6 26.9 57.4 91.9 52.5 35.1 52.5 54.8 91.9 15.4 15.4 30.2 22.6 54.1 8.5. 1 GHz 19.7 29.2 29.2 23.3 55.8 70.5 70.5 39.4 39.4 28.5 36.1 87 42.7 44.3 98.4 150.9 78.7 55.8 78.7 101.7 150.9 29.2 29.2 53.5 42.7 101.7 14.8. Vel. Factor % 78 66 66 66 66 66 66 66 66 84 84 66 69.5 69.5 66 69.5 69.5 69.51 69.5 69.5 69.5 66 66 66 69.5 69.5 84. WINDING WIRE DATA Cap. pF/m. Volt. Vrms. B&S SWG Gauges. Metric mm. 57.2 96.8 98.4 67.3 93.5 101 101 68.9 67.3 44.3 44.3 101 95.1 95.2 101 95.1 64 49.2 64 95.2 95.2 101 101 101 95.2 95.2 78.7. – 5000 5000 5000 1900 1900 1900 2300 2300 700 700 190 1900 1900 1500 1000 1200 1500 1200 1200 1200 5000 5000 1900 1900 1200 –. 12 – – – 13 – 14 – – 15 – – 16 – – 17 – 18 – – 19 – – 20 – 21 – – 22 – – 23 – – 24 – – – 25 – – 26 – – 27 – – 28 – – 29 – – 30 – – – 31 – – 32 – – 33 –. – – 2.000 – – 1.800 – – 1.600 – – 1.400 – 1.250 – – 1.120 – 1.000 – – 0.9000 – – 0.800 – – 0.7100 – 0.6300 – – 0.5600 – – – 0.5000 – – 0.4500 – – 0.4000 – – 0.3550 – – 0.3150 – – 0.2800 – – – 0.2500 – – 0.2240 – – – 0.1800 – –. Note: Except for Belden 9913, all specifications are referenced to MIL-C-17D/F or JAN-C-17A as applicable. Actual cables often exhibit lower losses than those specified above.. COPPER CABLE CHARACTERISTICS Number & Size of Strands 10 x 0.12 7 x 0.16 1 x 0.5 14 x 0.14 7 x 0.2 1 x 0.6 1 x 0.7 14 x 0.2 10 x 0.25 63 x 0.10 50 x 0.12 60 x 0.12 89 x 0.1 24 x 0.2 112 x 0.10 30 x 0.2 1 x 1.13 32 x 0.2 512 x 0.05 168 x 0.1 7 x 0.5 30 x 0.25 26 x 0.3 168 x 0.12 26 x 0.32 7 x 0.67 1 x 1.78 252 x 0.127 41 x 0.32 315 x 0.12 630 x 0.12 1666 x 0.12. Nominal Conductor Area (sq. mm) 0.11 0.14 0.20 0.22 0.22 0.28 0.38 0.44 0.49 0.49 0.55 0.68 0.70 0.75 0.88 0.94 1.0 1.0 1.0 1.32 1.4 1.5 1.8 1.9 2.1 2.5 2.5 3.2 3.3 3.6 7.13 18.84. Nominal Current Rating (Amps) 1.1 1.4 2.0 2.2 2.2 2.8 3.8 4.4 4.9 4.9 5.0 6.8 7.0 7.5 8.8 9.4 10.0 10.0 10.0 13.0 14.0 15.0 17.0 18.0 19.0 22.0 22.0 29.0 30.0 30.0 50 120. Maximum Resistance per metre (ohms 35°C) 0.17 0.13 0.10 0.088 0.086 0.067 0.049 0.043 0.039 0.039 0.035 0.028 0.027 0.025 0.022 0.020 0.019 0.019 0.019 0.014 0.014 0.013 0.010 0.010 0.0091 0.0077 0.0076 0.0059 0.0057 0.0053 0.0027 0.0010. PROPERTIES OF COPPER. Nearest Equivalent AWG (B&S) 27 26 24 24 24 23 21 21 20 20 20 19 19 18 18 17 17 17 17 16 16 15 15 14 14 13 13 12 12 12 9 5. (Based upon the IEC International Annealed Copper Standard.) Volume resistivity @ 20°C: 0.0000017241 ohm-cm Mass resistivity @ 20°C: 0.15328 ohm-grams/sq. metre Temperature coefficient @ 20°C: 0.0039 Tensile strength: 2350 kg/sq. cm Melting point: 1083°C. – 14 – 15 – – – 16 – – 17 – – – 18 – – – – 20 – – 21 – – – 22 – – – 23 – – 24 – 25 – 26 – – 27 – – 28 – – 29 – 30 31 – – 32 – 33 – 34 – – 35 – 36 – – 37. Dia. mils 1000ft 80.81 80.00 78.74 72.00 71.96 70.87 64.08 64.00 62.99 57.07 56.00 55.12 50.82 49.21 48.00 45.26 44.09 40.30 39.37 36.00 35.89 35.51 32.00 31.96 31.50 28.46 28.00 27.95 25.35 24.80 24.00 22.57 22.04 22.00 20.10 20.00 19.69 18.00 17.90 17.72 16.40 15.94 15.75 14.80 14.20 13.97 13.60 12.64 12.40 11.60 11.26 11.02 10.80 10.03 10.00 9.842 9.200 8.928 8.819 8.400 7.950 7.600 7.087 7.080 6.800. Ohms per 1.588 1.658 1.673 2.001 2.003 2.065 2.525 2.532 2.614 3.184 3.307 3.414 4.016 4.282 4.501 5.064 5.333 6.385 6.691 8.002 8.051 8.222 10.13 10.15 10.45 12.80 13.23 13.27 16.14 15.85 18.00 20.36 21.33 21.43 25.67 25.93 26.76 32.01 32.37 33.04 38.55 40.81 41.28 47.35 51.47 53.10 56.07 64.90 67.45 77.07 81.83 85.34 88.91 103.2 103.7 107.0 122.5 130.1 133.3 147.0 164.1 179.5 206.5 206.9 224.3. Dia. mm km 2.053 2.032 2.000 1.829 1.828 1.800 1.628 1.626 1.600 1.450 1.422 1.400 1.291 1.250 1.219 1.150 1.120 1.024 1.000 0.9144 0.9119 0.9000 0.8128 0.8120 0.8000 0.7231 0.7112 0.7100 0.6440 0.6300 0.6096 0.5734 0.5600 0.5588 0.5107 0.5080 0.5000 0.4572 0.4548 0.4500 0.4162 0.4050 0.4000 0.3759 0.3608 0.3550 0.3454 0.3211 0.3150 0.2946 0.2861 0.2800 0.2743 0.2548 0.2540 0.2500 0.2337 0.2268 0.2240 0.2134 0.2020 0.1930 0.1800 0.1799 0.1727. Ohms per 5.210 5.440 5.448 6.563 6.572 6.775 8.284 8.307 8.575 10.47 10.85 11.20 13.18 14.05 14.77 16.61 17.50 20.95 21.95 26.25 26.41 27.10 33.23 33.30 34.30 41.99 43.40 43.55 52.95 55.31 59.07 66.80 70.00 70.30 84.22 85.06 87.81 105.0 106.2 108.4 126.5 133.9 137.2 155.3 168.9 174.2 184.0 212.9 221.2 252.9 268.5 280.0 291.7 338.6 340.2 351.2 402.0 426.8 437.5 482.2 538.4 589.1 677.5 678.8 735.8. NOTE: Dick Smith Electronics does not stock all cables and wires shown. Data is presented for comparative purposes.. Note: The nominal current ratings are intended as guidelines for low power, electronics, communications and control applications only.. CHOOSE THE RIGHT CABLE The following 6 steps should help when trying to choose a suitable wire size for hooking up marine and auto accessories, extension speakers and the like. 1 Decide how much of the available supply voltage you are prepared to lose. All practical wires have some finite resistance, so it is impossible not to lose some voltage. 2 Divide the figure obtained in (1) by the maximum current which you expect to draw through the wire. This result is the tolerable resistance of your wiring. 3 Divide the result obtained in (2) by the total length (in metres) of the wiring loop. Include the distance from the power source to the load, and back again. This result is the maximum resistance of the desired wire in ohms per metre. 4 From the chart above, select a wire which has a ‘resistance per metre’ figure which is equal to or less than the desired value. 5 Check that the ‘nominal current rating’ in the table is not exceeded. If it is, then you may need to select a larger wire size with an adequate rating. While the figures given are conservative, they must not be exceeded in 240V applications and may need derating in higher temperature situations.. 392. see the full range at www.dse.com.au. 6 Finally, when purchasing the wire, verify that its insulation is rated to withstand the voltage and temperature for your particular application. EXAMPLE: You wish to install a 12V, 55W light on a boat. The current drawn by the light will be (55/12) 4.6 amps. You calculate that the length of the wiring loop is 5 metres. Step 1 Step 2 Step 3 Step 4 Step 5 Step 6. Lets say that you’ll tolerate a loss of 5% of the available 12V supply, i.e. 0.6V. Divide 0.6V by 4.6A to obtain 0.13 ohms. Divide 0.13 ohms by 5 metres to obtain 0.026 ohms per metre. Referring to the chart, you will find that 24 x 0.2mm wire appears to be suitable as its resistance is 0.025 ohms per metre. The ‘nominal current rating’ for this cable is 7.5A and on this basis it is still suitable. As you are dealing with a 12V system and are able to keep the wire away from hot areas and protect it from abrasion, there is unlikely to be any problem related to the insulation..
(7) 7770 Catalogue Pg 393 pc. 10/21/04. 12:54 PM. Page 393. Note: Some small signal transistors may have a TO-92 case and a ‘PN’ prefix. The electrical specifications are the same, only the case is changed. See case outline TO-92(72) for pin detail. Not all devices in this section are stocked by Dick Smith Electronics.. BIPOLAR TRANSISTORS TYPE MAT. CASE. POL. VCE mA. VCB. IC. BC107 BC108 BC109 BC109C BC177 BC178 BC179 BC327 BC328 BC337 BC338 BC546 BC547 BC548 BC549 BC549C BC556 BC557 BC558 BC559 BC639 BC640 BD139 BD140 BD262 BD263 BD266A BD267A BD681 BD682 BF173 BF199 BF463 BF469 BF470 BFR90 BFR91 BFY90 BUX80 MJ802 MJ2955 MJ4502 MJ10012 MJ15003 MJ15004 MJE340 MJE350 MJE2955T MJE3055T MPSA14 MPSA65 MRF629 MRF660 PN100 PN2907 PN200 TIP31B TIP32B TIP142 TIP147 TIP2955 TIP3055 2N2222A 2N3019 2N3053 2N3054 2N3055 2N3563 2N3564 2N3565 2N3566 2N3567 2N3568 2N3569 2N3638A 2N3641 2N3642 2N3643 2N3644 2N3645 2N3771 2N3866 2N3904 2N3905 2N3948 2N4030 2N4250 2N4258 2N4427 2N5401 2N6557 2SC710 2SC1306 2SC1307 2SC1674 2SC1969 2SC2166 2SC2694 2SC3355 2SC3358. TO-18 TO-18 TO-18 TO-18 TO-18 TO-18 TO-18 TO-92VAR1 TO-92VAR1 TO-92VAR1 TO-92VAR1 TO-92VAR1 TO-92VAR1 TO-92VAR1 TO-92VAR1 TO-92VAR1 TO-92VAR1 TO-92VAR1 TO-92VAR1 TO-92VAR1 TO-92(74) TO-92(74) TO-126 TO-126 TO-126 TO-126 TO-220 TO-220 TO-126 TO-126 TO-72(28) TO-92VAR2 TO-202 TO-126 TO-126 SOT-37(2) SOT-37(2) TO-72(25) TO-3 TO-3 TO-3 TO-3 TO-3 TO-3 TO-3 TO-126 TO-126 TO-220 TO-220 TO-92(72) TO-92(72) TO-39A TO-220A TO-92(72) TO-92(72) TO-92(72) TOP-66 TOP-66 TOP-3 TOP-3 TOP-3 TOP-3 TO-18 TO-39 TO-39 TO-66 TO-3 TO-106 TO-106 TO-106 TO-105 TO-105 TO-105 TO-105 TO-105 TO-105 TO-105 TO-105 TO-105 TO-105 TO-3 TO-39 TO-92(72) TO-92(72) TO-39 TO-39 TO-106 TO-106 TO-39 TO-92(72) TO-202 TO-92/76 TOP-66 TOP-66 TO-92(74) TOP-66 TOP-66 T-40 TO-92(74) MX. NS NS NS NS PS PS PS PS PS NS NS NS NS NS NS NS PS PS PS PS NS PS NS PS PS NS PS NS NS PS NS NS PS NS PS NS NS NS NS NS PS PS NS NS PS NS PS PS NS NS PS NS NS NS PS PS NS PS NS PS PS NS NS NS NS NS NS NS NS NS NS NS NS NS PS NS NS NS PS PS NS NS NS PS NS PS PS PS NS PS NS NS NS NS NS NS NS NS NS NS. 45 20 20 20 45 25 20 45 25 45 25 65 45 30 30 30 65 45 30 30 80 80 80 80 60 60 80 80 100 100 25 25 250 250 250 15 12 15 400 90 60 90 400 140 140 300 300 60 60 30 30 16 16 35 40 35 80 80 100 100 70 70 40 80 40 60 60 15 15 25 30 40 60 40 25 30 45 30 45 60 40 30 40 40 20 60 40 12 20 150 250 25 65 70 20 30 75 17 12 12. 50 30 30 30 50 30 25 50 30 50 30 80 50 30 30 30 80 50 30 30 100 100 100 100 60 80 80 100 100 100 40 40 250 250 250 20 15 30 800 100 70 100 600 140 140. 100 100 100 100 100 100 100 500 500 500 500 100 100 100 100 100 100 100 100 100 1A 1A 1.5A 1.5A 4A 4A 8A 8A 4A 4A 25 25 500 50 50 25 35 25 10A 30A 15A 30A 10A 20A 20A 500 500 10A 10A 500 500 400 2.4A 500 600 500 3A 3A 10A 10A 15A 15A 800 1A 700 4A 15A 50 100 50 200 500 500 500 500 500 500 500 500 500 30A 400 200 200 400 1A 100 50 400 6000 500 30 3A 8A 20 6A 4A 20A 100 100. 70 70 30 30 36 36 60 60 60 80 80 100 100 100 100 75 140 60 90 70 30 30 30 40 80 80 80 25 60 60 60 45 60 50 55 60 40 36 60 40 12 40 160 250 30 65 70 30 60 75 35 20 20. VCES @ IC mA 0.25 0.25 0.25 0.25 0.3 0.3 0.3 0.7 0.7 0.7 0.7 0.6 0.6 0.6 0.6 0.6 0.65 0.65 0.65 0.65 0.5 0.5 0.5 0.5 2.5 2.5 2 2 2.5 2.5. 0.3. 30. 1.5 0.8 1.1 0.8 2 1 1 0.75 0.77 1.1 1.1 1.5 1.5. 5A 7.5A 4A 7.5A 6A 5A 5A 100 100 4A 4A 100 100. 0.5 0.4 0.5 1.2 1.2 2 2 1.1 1.1 1.6 0.5 1.4 0.1 1.1. 100 150 150 3A 3A 5A 5A 4A 4A 500 500 150 200 4A. 0.3 0.35 1 0.25 0.25 0.25 0.25 0.22 0.22 0.22 1 1 2. 20 1 100 150 150 150 50 150 150 150 300 300 15A. 0.2 0.4. 10 50. 0.5 0.25 0.5 0.4 0.5. 500 10 50 100 50. 0.3. hFe. 10 10 10 10 10 10 10 500 500 500 500 100 100 100 100 100 100 100 100 100 500 500 500 500 1.5A 1.5A 3A 3A 1.5A 1.5A. @. 110-450 110-800 200-800 420-800 75-260 75-500 125-500 100-600 100-600 100-600 100-600 110-450 110-800 110-800 200-800 420-800 75-475 75-800 75-800 125-800 40-250 40-250 40-250 40-250 750 750 750 750 750 750 40-100 37 40-180 50 50 25-250 25-250 25-125 30 25-100 20-70 25-100 100-2K 25-150 25-150 30-240 30-240 20-100 20-100 20000 20000 20-200 20-160 60-240 100-300 50-400 25 25 >1000 >1000 20 20 100-300 50-100 50-250 25-100 20-70 20-200 20-500 150-600 150-600 40-120 40-120 100-300 100 40-120 40-120 100-300 100-300 100-300 15-60 10-200 100-300 50-200 15 25 250-700 30-120 10-200 60-240 >40 90 40-200 20-150 40-180 10-180 35-180 10-180 50-300 50-300. 10. Ic mA. FT MHz. 2 2 2 2 2 2 2 100 100 100 100 2 2 2 2 2 2 2 2 2 150 150 150 150 1.5A 1.5A 3A 3A 1.5A 1.5A 7 7 30 25 25 14 30 2 1.2A 7.5A 4A 7.5A 6A 5A 5A 50 50 4A 4A 100 100 100 250 150 150 150 1A 1A 5A 5A 4A 4A 150 500 150 500 4A 8 15 1 10 150 150 150 50. 300 300 300 300 150 150 150 100 100 100 100 300 300 300 300 300 200 200 200 200 130 50 250 75 7 7 7 7 1 1 550 550 20 60 60 5GHz 5GHz 1GHz 8 2 2.5 2. 150 150 150 15A 50 10 10 50 500 0.1 10 100 10 50 1 500 2A 1 10 100 1A 20 20. @. IC mA. PTOT mW. USE. COMPARABLE TYPES. 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10. 300 300 300 300 300 300 300 625 625 625 625 500 500 500 500 500 500 500 500 500 1W 1W 8W 8W 36W 36W 60W 60W 40W 40W 230 500 2W 1.8W 1.8W 180 180 200 100W 200W 115W 200W 175W 250W 250W 20W 20W 75W 75W 625 625 5W 25W 600 625 600 40W 40W 125W 125W 90W 90W 500 800 2.86W 25W 115W 200 200 200 300 300 300 300 300 350 350 350 300 300 150W 1W 310 310 1W 800 200 200 1W 625 2W 200 12W 25W 250 20W. G.P. S.S. amp. G.P. S.S. amp. Low noise S.S. amp Low noise high gain G.P. S.S. amp. G.P. S.S. amp. G.P. S.S. amp. Output Output Output Output G.P. S.S. amp. G.P. S.S. amp. G.P. S.S. amp. Low noise S.S. amp. Low noise high gain G.P. S.S. amp. G.P. S.S. amp. G.P. S.S. amp. G.P. S.S. amp. Audio O/P Audio O/P G.P. O/P G.P. O/P High gain Darl. O/P High gain Darl. O/P High gain Darl. O/P High gain Darl. O/P Darlington O/P Darlington O/P T.V. I.F. amp. H.F. amp. H.V. med. power. G.P. high-V. amp. G.P. high-V. amp. Wideband amp.. Wideband amp. Wideband amp. Deflection, high current SW High power output G.P. power High power output Power Darlington High power output High power output G.P. H.V. power G.P. H.V. power G.P. power G.P. power G.P. Darlington G.P. Darlington UHF power UHF power G.P. amp/switch High S. switch G.P. amp/switch Power output Power output Audio output Audio output Power output Power output High S. switch H.F. amp G.P. switch Audio output G.P. power RF – IF amp RF – IF amp Low level amp G.P. amp & switch G.P. amp & switch G.P. amp & switch G.P. amp & switch G.P. amp & switch G.P. amp & switch G.P. amp & switch G.P. amp & switch G.P. amp & switch G.P. amp & switch Power output VHF amp Low level amp G.P. amp & switch VHF amp G.P. amp & switch Low level amp Saturated switch VHF/UHF driver H.V. switch H.V. med power G.P. RF amp H.F. output H.F. output VHF amp H.F. output. BC207, BC147, BC182 BC208, BC148, BC183 BC209, BC149, BC184 BC209C, BC149C, BC184C BC157, BC307, BC212 BC158, BC308, BC213 BC159, BC309, BC214 2N3638 BC327 2N3642 BC337. 140W 600 250. VHF output UHF SS UHF SS. 50 50 1.5A 1.5A. 5 10 10 14 30 2 1A 500 1A. 2 2. 500 500. 2 2 125 100. 500 500 10 10. 350 200 200 3 3. 50 50 50 500 500. 3 3 300 100 100 0.8 2.5 600 400 400 40 60 60 60 150 250 250 250 200 200 0.2 500 300 200 700 260 50 700 500 100 45 100 300 150 600 150. 500 500 20 50 50 200 500 8 15 1 30 50 50 50 50 50 50 50 20 20 1A 50 10 20 50 100 10 50 10. 1. 800 6.5GHz 7GHz. 20 20. BC107, BC207, BC147 BC108, BC208, BC148 BC109, BC209, BC149 BC109C, BC149C BC157 BC158 BC159 MU9610, TT801 MU9660, TT800 40409 40410 BD266 BD267 BD263 BD262 BF180. TIP2955 TIP3055. PN2222, 2N3643 2N3638, BC214, PN3645 TIP140, TIP141 TIP145, TIP146 MJE2955 MJE3055 BD137 TIP31B BDY20 BF173 BF167 BC108, BC208 BC183 BC337 BC328 BC337 BC337 BC337 BC327. BC167A, BF194. BC559 2N3866 MPSL51 BFS18 2SC2166 2SC1969 2SC1307 MRF247 MRF573 MRF573. TRIACS Type BT137-500 BT139-500 BT139-600 BTA10-600B BTA41-600B Q4006L4 SC141D SC146D SC151D. CASE TO-220 TO-220 TO-220 TO-220 TOP-3 TO-220 TO-220 TO-220 TO-220. Vdrm. It (rms) (A). Ifsm (A). Igt (mA). 500 500 600 600 600 400 400 400 400. 8 16 16 10 40 6 6 10 15. 55 140 140 100 300 65 74 110 110. 35 (70-+) 35 (75-+) 35 (75-+) 50 (100-+) 50 (100-+) 25 (50-+) 50 (50-+) 50 (50-+) 50 (50-+). Vgt (T = 25°C). Pg (av) (W). 1.5 1.5 1.5. 0.5 0.5 0.5. 1.5 2.5 max all modes 2.5 ” 2.5 ” 2.5 ”. 1.0 0.9 0.5 0.5 0.5. Ih (mA) 20 30 30 50 80 60 max 50 max 50 max 50 max. dv/dt (V/uS). Comments (25°C). 100 100 100 100 @400V 250 100 typ 100 typ 150 typ 250 typ. (Gate o/c) (Gate o/c) (Gate o/c) (Isolated Tab) (Isolated Tab) (Gate o/c) (Gate o/c) (Gate o/c) (Gate o/c). see the full range at www.dse.com.au 393.
(8) 7770 Catalogue Pg 394 pc. 10/21/04. 12:54 PM. Page 394. Data FETS Type BF245B BF981 BF998 BFR84 MFE131 MPF102 MPF105 MPF106 MPF131 2N4342 2N5245 2n5247 2N5459 2N5484 2N5485 2N5486 3SK40 3SK121. Case TO-92 Var 1 SOT-103 SMT TO-72(2) TO-72(2) TO-92(72) TO-92(72) TO-92(72) 262 TO-92(72) TO-92(77) to-92(72) TO-92(72) TO-92(72) TO-92(72) TO-92(72) TO-72(2) 2-6F1A. BVgss V @ 30 >6 >6 >6 ±6 25 25 25 ±6 25 30 25 25 25 25 25 ±6 –5. Ig (uA) 1 ±10 100 ±10 10 1 1 ±10 10 1 10 1 1 1 1 ±10. Min 0.5 2.5 1.5 0.5 0.5 1.5 0.5 2 0.3 0.5 2 –2.5. Vgs (off) Max @ Vds 8 15 10 2.5 8 3.8 10 4 15 8 15 8 15 4 15 4 15 5 10 6 10 6 15 8 15 3 15 4 15 6 15 4 15 4 5. Id (nA) 10 20mA 20mA. Min 6 4 2 20. 200mA 2 10 10 200mA. 2 4 4 3 12 1 1 4 1 4 8. 10 10 10 10 10 200mA 100mA. 20. Idss (mA) Max @ Vds 15 15 25 10 18 10 55 10 30 15 20 15 16 15 10 15 30 15 30 10 18 5 15 9 15 5 15 10 15 20 15 25 15 45 5. Vgs 0 0 0/4 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0. Min 3000. 8000 2000 2000 2500 8000 1000 2000 3000 3500 4000 8000. YFS (umhos) Max @ 6500 14000 typ. 24000 typ. 15000 typ. 20000 7500 6000 7000 20000 6000 5800 typ. 5000 6000 6000 7000 8000. Ptot mW 300 225 200 300 300 310 310 310 350 180 360 625 310 310 310 310 250 200. Vds 15. 8 10 15 15 15 15 15 10 10 15 15 15 15 15 15 17000 typ. 10. Use/Comments N/CH Junction audio to H.F. N/CH Dual gate MOS. VHF AMP. N/CH VHF/UHF dual gate SMT N/CH VHF dual gate N/CH Dual gate MOS. VHF amp. N/CH Junction – VHF N/CH Junction – audio Sw. N/CH Junction – RF N/CH Dual gate MOS. VHF amp P/CH Junction – audio Sw. N/CH VHF/UHF MIXER n/ch Junction – audio Sw. N/CH Junction – audio Sw. N/CH Junction – VHF N/CH Junction – VHF N/CH Junction – VHF N/CH Dual gate MOS. VHF amp. N/CH UHF GaAs dual gate. POWER FETS Type BUK456-60A BUK456-60A BUK457-600B BUZ71A IRF520 IRfp450 MTP3055E php6n60e VN10K VN88AF 2SJ48 2SJ49 2SJ162 2SK133 2SK134 2SK1058 60n06. Ptot Case TO-220 TO-220 TO-220 TO-220 TO-220 to-247 TO-220 to-220 TO-92(76) TO-202F TO-3 TO-3 TOP-3 TO-3 TO-3 TOP-3 to-220. Vds (max) (W) 150 150 150 40 60 180 40 125 1 12.5 100 100 100 100 100 100 150. Id (max) (V) 60 60 600 50 100 500 60 600 60 80 120 140 160 120 140 160 60. Vgs (thres.) (A) 52 52 7.1 13 9.2 14 12 6.5 0.3 2 7 7 7 7 7 7 60. Gfs min 2.1 2.1 2.1 2.1 2 2.0 2 3.0 0.3 0.8 0.15 0.15 0.15 0.15 0.15 0.15 2.0. Ciss max 4 4 4 4 4 4.0 4.5 4.0 2.5 2 1.45 1.45 1.45 1.45 1.45 1.45 4.0. Rds umhos 17M 17M 8M typ. 4M 4M 14m 4M 5m 100K. (pF) 2000 2000 1800 600 350 2700 500 1500 48. (ohms) 0.028 0.028 1.2 0.12 0.25 0.4 0.15 1.2 5. 1M 1M 1M 1M 1M 1M 20M. 900 900 900 600 600 600 1950. 1 1 1 1 1 1 0.014. Comment Inverters Inverters Mains SMPS Nch power MOSFET Nch power MOSFET Nch power MOSFET Nch power MOSFET Nch power MOSFET Nch DMOS FET Nch VMOS FET Pch power MOSFET Pch power MOSFET Pch power MOSFET Nch power MOSFET Nch power MOSFET Nch power MOSFET Nch power MOSFET. SMALL SIGNAL DIODES Type Germanium OA47 OA90 OA91 DSOA91 1N60 OA95 Silicon BA102 BA234/4 BAW62 BB119 BB122 BB212 1N914A 1N4148 1N4448 5082-2800. Case. Vr. If (ma). DO-7 DO-7 DO-7 DO-7 DO-7 DO-7. 25 20 90 50 40 90. 110 45 50 30 30 50. DO-7 DO-35 SOD-27 DO-35 DO-35 TO-92 DO-35 DO-35 DO-35 DO-7. 20 20 75 15 30 12 75 75 75 70. 100 200. 75 200 300 15. Cd (pF). Vf. 3.5. 0.45 1.5 1.9 1 0.05 1.5. 1 1 20-45 <2 2 20-25 @ 4V 12 @ 3V 500-620 @ 0.5V 4 4 4 2. @. Cd Ratio 1.4 1 0.75 Cd Ratio >1.3 Cd Ratio 5.2 Cd Ratio >22.5 1 1 1 0.41. @ @. If(mA). Ir (ua). 10 10 10 5 0.375 10. 100 450 180 200 200 110. 25 20 75 10 10 0.75. 4V/10V 100 5 4V/10V. 0.1 5. 15 75. 4. 0.5V/8V 10 10 100 1. 0.05 0.05 5 0.025 0.025 0.2. 28 10 75 20 6 50. 4 4 4 0.1. @. Vr 600 400 1000. @. @. Vr. Trr (ns) 70. Use /Comparable Types Gold bonded G.P. switching G.P. point contact OA70, OA80 G.P. point contact OA71, 79, 81 G.P. OA91, 1N60 AM/FM detector G.P. point contact Variable capacitance UHF Sw. High speed silicon Sw. Varicap – replaces BA102 Varicap VHF UHF AM dual varicap Small signal Sw. 1N4148 Small signal Sw. 1N914A G.P. silicon Sw. 1N4148 Schottky, UHF detector, mixer switch. RECTIFIERS Type BYX98/600 1N4004 1N4007 BY229-400 1N4936 1N5404 1N5408 P600M 6a10 FB5006 3504 PO4 KBL04 KBPC804 KBL10/407 WO4 WO6 2WO6 DB155G 1N5819 1N5822. Vr 600 400 1000 400 400 400 1000 1000 1000 600 400 400 400 400 1000 400 600 600 600 40 40. If (a) 10 1 1 7 1 3 3 6 6 50 35 6 4 8 4 1.5 1.5 2 1.5 1 3. Ifsm (a) 75 30 30 60 30 200 200 400 350 500 400 200 200 200 50 30 50 50 25 80. Vf 1.4 1.1 1.1 1.85 1.3 1.1 1.1 0.9 1.0 1.2 (per leg) 1.2 (per leg) 1.3 (per leg) 1.1 (per leg) 1.0 (per leg) 1.1 (per leg) 1.1 (per leg) 1.1 (per leg) 1.0 (per leg) 1.1 (per leg) 0.6 0.525. @. If (A) 10 1 1 20 1 3 3 6 6 25 17.5 6 3 4 2 1 1 1 1 1 3. Ir (ua) 200 5 5 5 5 5 25 10 10 10 10 10 10 10 10 10 10 10 1mA 2mA. Use Power rectifier stud mount G.P. rectifier G.P. rectifier SMPS trr = 150nS SMPS trr = 200nS G.P. rectifier G.P. rectifier G.P. rectifier G.P. rectifier High current bridge High current bridge Medium duty mini bridge G.P bridge High current bridge G.P bridge SIL pins Mini bridge G.P bridge G.P bridge Mini bridge DIL pins Schottky barrier Schottky barrier. 400 400 1000 1000 1000 600 400 400 400 400 1000 400 600 600 600 40 40. SCRS VDRM TYPE BT151-500R BT169B C103B C106Y C106D C122D C122E C203B C220D PO103AA PO103AB S4008 S6008L SPS420 TYN608 TYN608G tyn816. 394. CASE TO-220 TO-92A TO-92 TO-202 TO-126/TO-202 TO-220 TO-220 TO-92A TO-48 TO-92A TO-92 TO-220 TO-220 TO-48 TO-220 TO-220 to-220. 500 200 200 30 400 400 500 200 400 100 100 400 600 400 600 600 800. see the full range at www.dse.com.au. IT (RMS) (A) 12 0.8 0.8 4 4 8 8 0.8 10 0.8 0.8 8 8 20 8 8 16. IFSM (A) 100 8 8 20 20 82 82 8 82 85 85 200 80 80 160. IGT (MA) 15 max .2 max .2 max .2 max .2 max 25 max 25 max .2 max 25 max .02-.2 .02-.2 25 max 25 max 25 max 15 max 25 max 25 max. VGT 1.5 max 0.8 max 0.8 max 0.8 max 0.8 max 1.5 max 1.5 max 0.8 max 1.5 max 0.8 max 0.8 max 1.5 max 1.5 max 2.0 max 1.5 max 1.5 max 1.5 max. PG (AV) (W) 0.5 0.1 0.01 0.1 0.1 0.5 0.5 0.01 0.5 0.1 0.1 0.5 0.5 0.5 – – 1. 20 5 5 5 3 3 30 5 30 5 5 30 30 50 30 45 40. max max max max max max max max max max max max max max max max max. DV/DT (V/US) 200 25 20 8 8 50 50 typ 20 typ 50 typ 100 typ 100 typ 50 typ 50 typ 200 200 typ 500 500 min. COMMENTS (25°C) (RGK=100) (RGK=1k) (RGK=1k) (RGK=1k) (RGK=1k) (Gate o/c) (Gate o/c). (Gate o/c) (Gate o/c) (Gate o/c) (Gate o/c).
(9) 7770 Catalogue Pg 395 pc. 10/21/04. 12:54 PM. Page 395. ZENER DATA Test Current Zener Volt. VZ@IZT (V). IZT (mA) 400mW. 1N746 1N747 1N748 1N750 1N751 1N752 1N753 1N754,1N957 1N755,1N958 1N756,1N959 1N757,1N960 1N758,1N961. 1N4728 1N4729 1N4730 1N4732 1N4733 1N4734 1N4735 1N4736 1N4737 1N4738 1N4739 1N4740. 3.3 3.6 3.9 4.7 5.1 5.6 6.2 6.8 7.5 8.2 9.1 10. 20 20 20 20 20 20 20 18.5 16.5 15 14 14. 1W. NOMINAL TEST CURRENT TYPE NO. W ZENER VOLT. TYPE NO. V 400MW SERIES 1 WATT SERIES VZ@IZT (V). 53 49 45 41 37 34 31 28 25. 1IN962 1N759, 1N963 1N964 1N965 1N966 1N967,1N4112 1N968 1N969 1N970 1N971 1N972 1N973. 1N4741 1N4742 1N4743 1N4744 1N4745 1N4746 1N4747 1N4748 1N4749 1N4750 1N4751 1N4752. IZT (MA) 400MW. 1W. 12.5 11.5 10.5 9.5 8.5 7.8 7 6.2 5.6 5.3 5.3 5.2. 23 21 19 17 15.5 14 12.5 11.5 10.5 9.5 8.5 7.5. 11 12 13 15 16 18 20 22 24 27 30 33. Temperature co-efficient range for 1W units to 12V. Temperature co-efficient. Type No. V 400mW Series. Nominal Type No. W 1 Watt Series. W (DC Power Dissipation: 1 W @ 50°C Ambient) (Derate 6.67mW/°C above 50°C). This range will dissipate up to 3W @ 75°C with 10mm lead length as heatsink.. V (DC. Power Dissipation: 400 milliwatts @ 50°C Ambient) (Derate 3.2mW/°C above 50°C). DISCRETE OPTOELECTRONICS 7-SEGMENT LEDS Z 4118. Z 4104. Z 4146. Z 4118. Z-4130. Z4146. Anode 7.6mm Red 25mA 1.7 5 100uA 450ucd 55mW. Cathode 13.2mm Red Red 25mA 1.7 2.0 5 5 100uA 450ucd 55mW. Anode 7.6mm Orange 25mA 2.0 5 100uA 500ucd 55mW. Anode 14.2mm Red 25mA 1.7 5 10uA 750ucd 85mW. Cathode 13.1mm. Anode. 25mA. 25mA. 5 10uA 4500ucd 100mW. 8500ucd 110mW. 10 9 8 5 4 2 3 7 1, 6. 7 6 4 2 1 9 10 5 3, 8. 7 6 4 2 1 9 10 5 3,8. 7 6 4 2 1 9 10 5 3,8. Characteristics Common terminal pol. Digit size 7.6mm Colour Red Av. fwd. seg. current Segment voltage 1.7 Min. rev. brkdn. volt. Max. rev. current 100uA Seg. intensity (typ.) Max. seg. dissipation. Z 4145 Z 4150 Z 4151 Z 4130 Z 4133 Z 4146. Connections Seg. A Seg. B Seg. C Seg. D Seg. E Seg. F Seg. G Dec. Pt. Common. 1 13 10 8 7 2 11 9 3, 14. 1 13 10 8 7 2 11 9 3, 14. Z 4103 Z 4105 Z 4117 Z 4118. Note: Not all devices in this section are stocked by Dick Smith Electronics.. Z 4170 / Z 4172 LIQUID CRYSTAL DISPLAYS 80.0 ± 0.5. The Z 4170 and Z 4172 are self-contained Liquid Crystal Displays (LCDs). Both modules can display 2 rows of 16 characters, and both include a CMOS interface and drive IC to enable simple connection to a 4 or 8-bit microprocessor. 96 alpha-numeric characters are available from an in-built character generator, and up to 8 characters can be user defined. The Z 4172 includes a backlight feature. A full data sheet is included with each unit.. 75 ± 0.3. 8.0. P2.54x15=38.1. 16 x ø1.0 4 x ø2.5. Interface Pin Functions 1. Function Ground (0V) Logic supply (+5V) Contrast adjustment Data/instruction select Read/write select Signal enable Data bus LED backlight (Z 4172 only) LED backlight (Z 4172 only). 15.24. 11.5. 7.58. 17.2 ± 0.2. 26.2 ± 0.3. k. 2.5. 56.2. 71.2 ± 0.3. 2.54. Silicon PIN photo diode encapsulated in a black plastic package which acts as an infrared filter. Vr max Ptot Tj Idr Ilr lpk. A. 64.0 ± 0.2. Z 1956 SILICON PIN INFRARED PHOTO DIODE Reverse voltage Power dissipation @ 25°C Junction temperature Dark reverse current (Vr=10V Ee=0) Light reverse current (Ee=5mW/cm2) Wavelength of peak response. 16. ø1.0 31.0 ± 0.3. Symbol Vss Vdd VO RS R/W E D0-D7 A K. 36.0 ± 0.5. Pin No 1 2 3 4 5 6 7-14 15 16. 30V 100mW 100°C 30nA 200uA typ 940nm. Z 3235 INFRARED EMITTING DIODE High Intensity Gallium Arsenide infrared emitting diodes intended for remote control applications. Smoke coloured end looking encapsulation. Forward voltage Continuous reverse voltage Forward current (d.c.) Peak forward current (300pps, 1us pulse) Total power dissipation up to Tamb=25°C Junction temperature Radiant incidence @ If=20mA Wavelength of peak emission. Vf Vr If max Ifpk Ptot max Tj Eo lpk. 1.2V @ 20mA 5V 50mA 3A 100mW 100°C 1mW/cm2 940nm. see the full range at www.dse.com.au 395.
(10) 7770 Catalogue Pg 396 pc. 10/21/04. 12:53 PM. Page 396. Data TYPE Z 3820 Z 3800 Z 4077 Z 4079 Z 4081 Z 4083 Z 3902 Z 3905 Z 3980 Z 3982 Z 4015 Z 4033 Z 4071 Z 4072 Z 4074 Z 4031 Z 4085 Z 4087 Z 4089 Z 4091 Z 4044 Z 4046 Z 4060 Z 4067 Z 4200 Z 4202 Z 4204. NOMINAL SIZE (mm) 3 dia. 3 dia. 3 dia. 3 dia. 3 dia. 3 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 5 dia. 10 dia. 10 dia. 1.8 x 5.0 1.8 x 5.0 1.8 x 5.0. Blue White Red Green Yellow Orange Blue Blue White White Green Amber yellow Red/green Red Red Sunset red Red Green Yellow Orange Flashing red Flashing green Red Red Red Green Yellow. LENS Water clear Water clear Red diffused Green diffused Yellow diffused Orange diffused Water clear Water clear Water clear Water clear Water clear Water clear White diffused Water clear Water clear Water clear Red diffused Green diffused Yellow diffused Orange diffused Red Green Red diffused Water cear Red Red Yellow. HIGH PERFORMANCE LEDs MAX. CONT. FWD. MAX. REV. HIGH PERFORMANCE LEDs CURRENT (mA) VOLTAGE. FWD. VOLTAGE (@ 20mA) 3.5 3.5 2.1 2.2 2.2 2.0 3.5 3.6 3.6 5 3.5 2.0 2.0 1.8 1.8 2.0 2.1 2.2 2.2 2.0 12 12 2.0 1.9 2.1 2.1 2.1. 30 30 15 30 20 30 30 30 30 20 30 50 25 40 40 50 15 30 20 30 60 60 30 50 30 30 30. 5 5 5 5 5 5 5 5 5 5 5 5 5 4 4 5 5 5 5 5 5 5 5 5 5 5 5. LUMINOUS @ INTENSITY (mcd) 700 1500 2 18 15 15 1800 5600 2300 8000 14000 6500 126/49 1000 2300 8000 3 15 12 12 390 98 40 6000 5.1 27 27. CURRENT (mA) 20 20 10 10 10 10 20 20 20 30 20 20 20 20 20 20 10 10 10 10 25 25 20 20 20 20 20. PEAK WAVELENGTH (nm) 468 – 697 565 585 635 475 475 – 456 512 595 660/567 660 660 640 697 565 585 635 660 567 625 660 690 565 565. Z 4077, Z 4079, Z 4081, Z 4083. Z 4072. Z 4093, Z 4095. Z 3900, Z 4085, Z 4087, Z 4089, Z 4091. Z 4071 Dual Colour. + –. FLASHING LEDs. Nominal size Operating voltage range Intensity (typ. @ 10V) Peak wavelength Flash rate (approx @ 10V) Duty cycle Max. rev. voltage. USING LEDs. Z 4042 GREEN. Z 4044 RED. Z 4046 GREEN. UNITS. 5 3-10 10 565 2 25 0.6. 5 3-15 390 660 2.4 25 5. 5 3-15 98 567 2.4 25 5. mm V mcd nm Hz % V. Z 4801 LIGHT DEPENDENT RESISTOR (LDR) RATINGS Max. voltage Power dissipation (at 25°C). 100V 50mW. CHARACTERISTICS Dark resistance Resistance @ 10 Lux Peak spectral response. > 10 M ohm 48-140k ohm 560-620 nm. The approximate relationship between illumination and resistance is given by, -0.85. R = AL where; R = resistance, A = a constant (approx. 340-990 x 10 ), L = light level in Lux 3. 396. see the full range at www.dse.com.au. When using a Light Emitting Diode (LED) as an indicator, use the following formula to determine series resistance for various voltages: R = (E-Vf) x 1000/l, where R is the resistance in ohms, E is the DC supply voltage, I is the LED current in mA and Vf is the forward voltage drop of the LED, typ. 2V. ie.. With Vf=2V, LED current=20mA, for 6V, R=220 ohms 9V, R=330 ohms 12V, R=560 ohms 24V, R=1200 ohms. Note: This does not apply to flashing LEDs. Flashing LEDs can be driven from a voltage source, ie without a resistor.. Z 4710 BR100/03 Breakover voltage at dV/dt=10V/ms Breakover voltage symmetry Breakover current at V=0.98 VBO Maximum power dissipation. VBO Vs IBO PTOT. 28 to 36V 3V 100µA 150mW.
(11) 7770 Catalogue Pg 397 pc. 10/21/04. 12:53 PM. Page 397. SEMICONDUCTOR OUTLINES. TO-18. TO-5. TO-3. TO-1. BOTTOM VIEW UNLESS OTHERWISE STATED. 79-03 TO-39(A). TO-39. TO-39(mod). TO-72(2) TO-48 SIDE VIEW. TO-66. TO-92 VAR.1. TO-72. C(A). TO-220. TO-220(A). FET. SCR. SOT-37(2) TOP VIEW. TO-202. SOT-103 TOP VIEW. TO-202R TO-202FET TO-202 FRONT VIEW. TO-202SCR. TO-126 FRONT VIEW. TO-127 FRONT VIEW. TOP-3 FRONT VIEW. TOP-66 FRONT VIEW. TO-247 FRONT VIEW. SOT-30. MX TOP VIEW. 206 TOP VIEW. 262 TOP VIEW. 2-6F1A. DIODES. ZENER DIODES. D6 TOP VIEW. D8 TOP VIEW. GDS. TRIAC. TO-220 FRONT VIEW. TO-92 A SCR. B(G). E(K) TO-106. TO-92 SCR. Rear metal area is C. Rear metal area is C (A). TO-105. TO-92 VAR.2. E C E. MT-72C FRONT VIEW. E B E T-40 TOP VIEW. NTC THERMISTOR These Negative Temperature Coefficient (NTC) Thermistors are useful for temperature sensing, temperature compensation, automatic gain control and fluid flow monitoring. They are not for use in conducting, reducing or aggressive gases or fluids. The resistance of the R1890 and R1895 can be calculated from the formula:. R = AeB/T where,. R is the thermistor resistance in ohms, T is the temperature in Kelvin, e is the natural logarithm base (2.718) and A & B are constants which should be calculated from measurements on each particular thermistor for best accuracy.. SPECIFICATIONS Maximum permissible current Operating temperature range at zero power Thermal time constant Resistance value at 25°C B-Constant (@ 25° and 85°C). R 1890. R 1895. 25mA -20°C to +125°C 18s 100k ohms 4400. 10mA -30°C to +125°C 24s 100k ohms 4400. For nominal values of B and R, A is approximately 0.0277.. see the full range at www.dse.com.au 397.
(12) 7770 Catalogue Pg 398 pc. 10/21/04. 12:52 PM. Page 398. Data OPERATIONAL AMPLIFIERS HANDY REFERENCE GUIDE. TYPE LM301 LM741 LM308 NE5534 OP27 TL071 LF351 TLC251 CA3130 CA3140 LM10CL LM3080 LM627 LM1458 LM358 LM833 TL072 LF353 LM13600 LM324 UA4136 TL074 LF347 LM614 LM3900. DEVICE SINGLE OP AMPS GP amplifier GP amplifier Low input current Low noise Low noise precision JFET low noise JFET low noise Prog low power CMOS MOSFET input MOSFET input Inc. voltage Ref. Transconductance Precision Op-amp DUAL OP AMPS GP amplifier Low power Hi-Fi JFET low noise JFET low noise Transconductance QUAD OP AMPS GP amplifier GP low noise JFET low noise JFET low noise Inc. volt Ref. Norton amp. INPUT OFFSET VOLT. MAX (mV). INPUT OFFSET CURRENT MAX (nA). INPUT BIAS CURRENT MAX (nA). VOLT. GAIN MIN (VOLTS/V). UNITY GAIN B.W. TYP (MHz). SLEW RATE AV=1 TYP (V/US). OUTPUT VOLT. SWING R1=10K (VS=+/-15) (V). SUPPLY. VOLTAGE. SUPPLY CURRENT TA=25C CMRR DIFFERENTIAL (NOTE 1) INTERNAL MIN INPUT VOLT. MAX FREQ. (dB) (V) (mA) COMP.. MIN (V). MAX (V). 10 7.5 10 5 0.22 13 13 10 15 15 5 5 0.1. 70 300 1.5 400 135 2 4 0.3 0.03 0.03 3 500 25. 300 800 10 2000 150 7 8 0.6 0.05 0.05 40 5000 25. 15k 15k 15k 15k 450k 15k 15k 7.5k 50k 20k 3k 5.4mmho 4M. 1 1 1 10 5 3 4 0.7 4 4.5 0.1 2@Ao1 14. 0.5 0.5 0.3 6 1.7 13 13 0.6 10 9 * 50 4.5. +/-12 +/-12 +/-13 +/-12 +/-11 +/-12 +/-12 7.8(Vs=10V) +/-6(Vs=+/-8) +/-12 6.94(Vs=7v) +/-12 +/-14.0. +/-3 +/-3 +/-2 +/-3 +/-4 +/-3.6 +/-4 1.4 +/-2.5 +/-2 1.1 +/-2 +/-3.5. +/-18 +/-18 +/-18 +/-22 +/-22 +/-18 +/-18 18 +/-8 +/-18 7 +/-18 +/-18. 70 70 80 70 96 70 70 60 70 70 74 80 120. +/-30 +/-30 +/-1.0(Note2) +/-0.5(Note2) +/-0.7(Note2) +/-30 +/-30 +/-18 +/-8 +/-8 +/-7 +/-5 25mA(Note2). 3 2.8 0.8 8 5.7 2.5 3.4 0.22 15 6 0.57 typ 1.1 4.8. No Yes No No Yes Yes Yes Yes No Yes Yes No Yes. 7.5 9 5 13 13 4. 300 150 200 2 4 600. 800 500 1000 7 8 8000. 15k 15k 30k 15k 15k 5.4mmho. 1 1 15 3 4 2@Ao1. 0.5 0.5 7 13 13 50. +/-12 +/-12 +/-12 +/-12 +/-12 +/-12. +/-3 +/1.5 +/-5 +/-3.6 +/-6 +/-2. +/-18 +/-16 +/-18 +/-18 +/-18 +/-18. 70 65 80 70 70 80. +/-30 32 +/-30 +/-30 +/-30 +/-5. 5.6 2 8 5 6.5 typ 2.6. Yes Yes Yes Yes Yes No. 9 7.5 13 13 7 *. 150 300 2 4 50 *. 500 800 7 8 250 200. 15k 15k 15k 15k 25k 1.2k. 1 3 3 4 >1 2.5. 0.5 1 13 13 0.8 20. +/-13 +/-12 +/-12 +/-12 12.4 10. +/-1.5 +/-2 +/-3.6 +/-4.5 +3 +4. +/-16 +/-18 +/-18 +/-18 +36 +32. 65 70 70 70 80 *. 32 +/-30 +/-30 +/-30 36 *. 3 11 10 11 typ 0.8 10. Yes Yes Yes Yes Yes Yes. * Not Specified. Note 1: Supply current for all channels in the package. Note 2: Inputs have shunt diode protection, current must be limited. Note 3: Dick Smith Electronics may not stock all devices listed.. *. *. 301, 308. *301 only. LM627, OP27. LM3900. LM324, TL074, LF347. AMPLIFIER CONFIGURATIONS. TLC251. 741, TL071, LF351, AD711. Inverting Amplifier. CA3130, CA3140. *CA3130 ONLY. UA4136. Non-Inverting Amplifier. 308 LM10. Voltage Follower. K. NE5534. 398. see the full range at www.dse.com.au. TL072, LF353, LM833, 1458, AD712, LM358. LM614.
(13) 7770 Catalogue Pg 399 pc. 10/21/04. 12:52 PM. Page 399. 555 TIMER (LM/NE555 BIPOLAR, TLC555 CMOS) GENERAL The 555 Timer is a highly versatile low-cost IC specifically designed for precision timing applications. It can also be used in monostable multi-vibrator, astable multi-vibrator and Schmitt trigger applications. BIPOLAR 555 The 555 has many attractive features. It can operate from 4.5 volts to 16 volts. Its output can source (supply) or sink (absorb) load current up to a maximum of 200mA and so can directly drive loads such as relays, LEDs, low-power lamps, and high impedance speakers. When used in the ‘timing’ mode, the IC can readily produce accurately timing periods variable from a few microseconds to several hundred seconds via a single R-C network. Timing periods are virtually independent of supply rail voltage, have a temperature coefficient of only .005% per ˚C, can be started via a TRIGGER command signal, and can be aborted by a RESET command signal. When used in the monostable mode, the IC produces output pulses with typical rise and fall times of a mere nS. When used in the astable mode both the frequency and the duty cycle of the waveform can be accurately controlled with two external resistors and one capacitor. CMOS 555 Due to its high impedance inputs (typically 1012Ω), it is capable of producing accurate time delays and oscillations while using less expensive, smaller timing capacitors than NE555. Like the NE555, the TLC555 achieves both monostable (using one resistor and one capacitor) and astable (using two resistors and one capacitor) operation. In addition, 50% duty cycle astable operation is possible using only a single resistor and one capacitor. The TLC555 will operate at frequencies up to 2MHz and is fully compatible with CMOS, TTL, and MOS logic. While the complementary CMOS output is capable of sinking over 100mA and sourcing over 10mA, the TLC555 exhibits greatly reduced supply current spikes during output transitions. This minimises the need for the large decoupling capacitors required by the NE555.. MONOSTABLE OPERATION In the monostable mode, the timer functions as a one-shot. Referring to the circuit the external capacitor is initially held discharged by a transistor inside the timer. When a negative trigger pulse is applied to lead 2, the flip-flop is set, releasing the short circuit across the external capacitor, driving the output HIGH. The voltage across the capacitor, increases exponentially with the time constant t=R1C1. When the voltage across the capacitor equals 2/3 VCC, the comparator resets the flip-flop which then discharges the capacitor rapidly and drives the output to its LOW state. The circuit triggers on a negative-going input signal when the level reaches 1/3 VCC. Once triggered, the circuit remains in this state until the set time has elapsed, even if it is triggered again during this interval. The duration of the output HIGH state is given by t=1.1 R1C1. The timing interval is independent of supply. When Reset is not used it should be tied high to avoid any possibility of false triggering. ASTABLE OPERATION When the circuit is connected as shown it triggers itself and free runs as a multivibrator. The external capacitor charges through R1 and R2 and discharges through R2 only. Thus the duty cycle may be precisely set by the ratio of these two resistors. In the astable mode of operation, C1 charges and discharges between 1/3 VCC and 2/3 VCC. As in the triggered mode, the charge and discharge times and therefore frequency are independent of the supply voltage. The charge time (output HIGH) is given by: t1 = 0.693 (R1 + R2) C1 and the discharge time (output LOW) by: t2 = 0.693 (R2) C1 Thus the total period T is given by: T = t1 + t2 = 0.693 (R1 + 2R2) C1 The frequency of oscillation is then: f=. 1 1.44 = T (R1 + 2R2) C1 R2 R1 + 2R2. 100 100. R1. 1. 1k Ω. Ω 0k. Supply Voltage Supply Current Power Dissipation Threshold Voltage Threshold Current Trigger Voltage Trigger Current Reset Voltage Reset Current High Level Output Low Level Output Output Current. Basic Astable Circuit. kΩ. Basic Monostable Circuit. 10. 10 s. Ω. TA = 25˚C PARAMETERS. 0.01 (R1+2R2 ). 0.001 0.1. Time Delay vs R1 and C1. SPECIFICATIONS. 0.1. Ω. 10 U S 100 U S 1 ms 10 ms 100 ms 1 s t d- TIME DELAY. 1 M. 0.01. 0.001. 10. 10. Ω Ω Ω 1K KΩ 0K Ω M 10 1M 10 10. 1M. 0.1. CAPACITANCE (uF). 10. 10. CAPACITANCE (u F ). The duty cycle is given by: D =. 1. 10 100. 1k 10k 100k. Free Running Frequency. VCC = 15V UNLESS OTHERWISE STATED. LM/NE555C LIMITS CONDITIONS MIN TYP MAX. TLC555C LIMITS CONDITIONS MIN TYP MAX. 4.5. (Iol=100mA) (Iol=100mA) Sink Source Initial Error of Timing Interval. 16V 2 18 10mA 15mA (RL=∞, Vop=low) 360uA 600mW 600mW 67% (%of Vcc) 67% 0.1 0.25uA (Vcc=5V) 10pA 33% (% of Vcc) 33% 0.5uA (Vcc=5V) 10pA 0.4 0.5 1V 0.4 1.1 1.5 0.1 0.4mA (Vcc=5V) 10pA 12.75 13.3V (Iol=10mA) 12.5V 14.2V 2 2.5V (Iol=100mA) 1.28V 3.2V 200mA 100mA 200mA 10mA 1% 1%. FUNCTION TABLE TRIGGER THRESHOLD RESET VOLTAGE VOLTAGE Low Irrelevant Irrelevant High <1/3 Vcc Irrelevant High >1/3 Vcc >2/3 Vcc High >1/3 Vcc <2/3 Vcc. DISCHARGE OUTPUT SWITCH Low On High Off Low On As previously established. (RL=∞, Vop=low) (% of Vcc) (% of Vcc). see the full range at www.dse.com.au 399.
(14) 7770 Catalogue Pg 400 pc. 10/21/04. 12:51 PM. Page 400. Data VOLTAGE REGULATORS. TYPICAL POWER SUPPLY. THREE TERMINAL VOLTAGE REGULATORS These voltage regulators almost make power supply building unnecessary since they require only a filtered DC voltage input. They are essentially indestructible (if used within manufacturer’s specs) because of internal current limiting and thermal shutdown should a short occur. They are ideally suited to local, on-board regulation simplifying power supply distribution systems. Excellent for TTL and project supplies. With the advent of microprocessors and microcomputers, these regulators have been used extensively in power supplies for such systems. This type of use typifies their versatility and reliability. Another area of supply regulation use is with analogue operational amplifiers. These circuits usually call for both + and – complementary rail voltages. These three terminal devices ideally suit such requirements.. OUTPUT: 5V @ 1A The same basic circuit can be used with other regulators of different voltages, only the input AC voltage has to be changed to accommodate the requirement of the regulator, E.g. If an output of 12V was the requirement, a 7812 IC could be used with an AC input voltage of 15V.. The addition of protection diodes, as shown in the 317/350 application circuit, is recommended if there is any possibility of the regulator input or output being shorted to ground. These may also be necessary if significant (1uF) capacitance is connected between ground and either the common or output terminals of the regulator. TYPE POL CASE VIN VOUT IOUT DROPMAX MIN TYP. MAX (NOM) OUT A. VOLT. 78L05Z pos. TO-92 30 4.8 5 5.2 0.1 2.2 78L12Z pos. TO-92 30 11.5 12 12.5 0.1 2.2 78L15Z pos. TO-92 35 14.4 15 15.6 0.1 2.2 7805T pos. TO-220 35 4.8 5 5.2 1 2.5 7808T pos. TO-220 35 7.7 8 8.3 1 2.5 7812T pos. TO-220 35 11.5 12 12.5 1 2.5 7815T pos. TO-220 35 14.4 15 15.6 1 2.5 7805K pos. TO-3 35 4.8 5 5.2 1 2 7812K pos. TO-3 35 11.5 12 12.5 1 2 7815K pos. TO-3 35 14.4 15 15.6 1 2 7905T neg. TO-220 35 -4.8 -5 -5.2 1 2.3 7912T neg. TO-220 35 -11.5 -12 -12.5 1 2.3 7915T neg. TO-220 35 -14.4 -15 -15.6 1 2.3 7905K neg. TO-3 35 -4.8 -5 -5.2 1 2.3 LM317T pos. TO-220 40 adj. 1.2 to 37 1.5 3 LM317K pos. TO-3 40 adj. 1.2 to 37 1.5 3 LM350T pos. TO-220 35 adj. 1.2 to 32 3 3 LM350K pos. TO-3 35 adj. 1.2 to 32 3 3 LM337T neg. TO-220 40 adj. -1.2 to -371.5 3 LM-2940CT-5 pos. TO-220 26 4.75 5 5.25 1 <1 LM-2940T-8 pos. TO-220 26 7.6 8 8.4 1 <1 LM-2940T-10 pos. TO-220 26 9.5 10 10.5 1 <1 LM-2940CT-12 pos. TO-220 26 11.4 12 12.6 1 <1 LM-2941CT pos. TO-220 26V adj. 5 to 20 1.5 <1 For all devices listed, the maximum junction temperature is 125°C. Except for TO-92 packages, maximum junction to case thermal resistance is 4°/watt. For TO-92 packages, junction to ambient thermal resistance is 230°/W. TO-220 Package 78XX, LM340, LM2940 Positive Regulator Series. TO-220 Package 79XX, LM320 Negative Regulator Series. TO-3 Package 78XX, LM340 Positive Regulator Series. TO-3 Package 7905, LM320 Negative Regulator Series. LM317 OR LM350 SERIES. 1. Choose Resistor R as follows: R = (96 x Vout) – 120 Where R is in ohms and Vout is in volts. 2. Vin should be at least 2.5 volts greater than Vout. 3. Capacitor voltage ratings must be chosen appropriately.. LM335 PRECISION TEMPERATURE SENSOR. 4. The protection diodes shown will be necessary if the input or output of the regulator is shorted to ground. 1A types should be adequate.. LM334 ADJUSTABLE CURRENT SOURCE. The LM335 operates as a two terminal zener having a breakdown voltage directly proportional to absolute temperature (10mV per Kelvin). An adjustment terminal is provided, and maximum accuracy is realised when this is used to set the output voltage to 2.982 volts @ 25°C. Max. rev. current Continuous operating temp. Operating output voltage (Tc = 25°C, I = 1mA) typ Max. uncalibrated temp. error (Tc = 25°C, I = 1mA) Output voltage tempco. Dynamic impedance Non-linearity (I = 1mA). Operating voltage 1-30 Max power dissipation 200mW. 15mA -40°C to 100°C. Voltage sensitivity 0.1%/V. 2.98V. Temperature sensitivity +0.33%/°C. 6°C 10mV/°C 0.6 ohms 1.5°C. LM336 REFERENCE DIODES Max fwd current (mA) Untrimmed ref voltage Dynamic impedance (ohms) Temp stability (0-70°C). LM336-2.5 10 2.44-2.54 1 20ppm. LM336-5.0 10 4.9-5.1 2 20ppm. INCREASING THE OUTPUT CURRENT OF THE REGULATOR By adding a PNP power transistor to a positive regulator, the output current can be increased above the normal rating of the regulator itself. The circuit shown below can be expected to deliver in excess of 4A with the pass transistor mounted on a heatsink. The same conditions can also be implemented with a negative regulator, the difference being the polarities of components, the pass transistor in this case would be an NPN type such as a 2N3055.. USING THE LM317 OR LM350 AS A CURRENT REGULATOR TO-220 Package LM317, LM350 Positive Regulator. TO-3 Package LM317, LM350. Vin. LM 317 or LM 350. Vout. lout R1. ADJ TO-220 Package LM337 Negative Regulator. Load. TO-92 Package 78LXX Positive Regulator Series. Vref typically 1.25V. 400. see the full range at www.dse.com.au. lout = Vref / R1.
(15) 7770 Catalogue Pg 401 pc. 10/21/04. 12:51 PM. Page 401. Z 6070 TDA2822M DUAL LOW-VOLTAGE POWER AMPLIFIER The TDA2822M offers low voltage, low quiescent current operation and high power output from an 8-pin DIP package. SPECIFICATIONS: Supply voltage: Quiescent current: Gain: Channel balance: Input resistance: Power output (typ.): (1kHz, 10% dist.):. Rth j-amb: Rth j-pin: Max junction temp:. 1.8-15 volt 9mA max 39dB typ 1dB 100k ohm 220mW @ 6 volt, 16 ohms 380mW @ 6 volt, 8 ohms 1000mW @ 9 volt, 8 ohms 650mW @ 6 volt, 4 ohms 110mW @ 3 volt, 4 ohms 100 K/W 70 K/W 150˚C. LM1875 20 WATT AMPLIFIER IC The LM1875 is a monolithic power amplifier IC which takes advantage of advanced techniques to achieve low distortion, even at high output levels. Other features include high gain, fast slew rate and a wide power bandwidth, large output voltage swing, high current capability and wide supply range. The device is internally compensated for gains of 10 and greater. SPECIFICATIONS: Supply voltage: Quiescent current: THD 20W/1KHz: Open loop gain: Current limit: Thermal resistance: (junction to case) Junction temperature:. +/-30 volt max 100mA max 0.015% typ 90dB typ 4A typ 2°C/W typ 150°C max. LM386 POWER AMPLIFIER The LM386 power amplifier IC is ideal for low voltage applications. The gain is internally set at 20, but may be increased up to 200 by adding components between pins 1 and 8. Gain 20 50 100 200. Rg ∞ 680 180 0. Vs (volts) 12 9 6 5. Output Power (mW) Rl (ohms) 4 8 380 660 380 560 250 250 190 160. 16 780 400 150 90. L. LM380 2.5 WATT AMPLIFIER IC The LM380 is an amplifier IC for general purpose audio applications such as intercoms, small audio amplifiers, headphone amplifiers, TV and radio sound. The output is shortcircuit proof and the device has internal thermal limiting. It is also suitable for low power DC operation such as for controlling a small motor or servo control. The gain is internally set at 34dB, a voltage gain of 50. SPECIFICATIONS: Supply voltage: Gain: Output power: Peak current: Input resistance: Bandwidth: THD: Quiescent current:. 10-22 volts 34dB 2.5 watt (min.) (into 8 ohms, @ 3% THD) 1.3 amps 150k ohms 100kHz <0.2% 7mA typ. see the full range at www.dse.com.au 401.
(16) 7770 Catalogue Pg 402 pc. 10/21/04. 12:50 PM. Page 402. Data COMMON CONNECTORS DIN CONNECTORS Contact Arrangement MALE PLUG. Application 2. 1. Mono Microphone (balanced) Mono (unbalanced) Stereo (balanced). 3 PIN XLR CONNECTORS. Connections Hot lead. 3. 4. 5. Return lead. Hot lead Hot lead of left-hand channel. Return lead of left-hand channel. Hot lead of right-hand channel. Return lead of right-hand channel. Microphone Stereo (unbalanced). FEMALE SOCKET. Turntable. Tape Recorder. Hot lead of left-hand channel Screen earth. Hot lead. Connected to 3. Hot lead of left-hand channel. Hot lead of right-hand channel. Input signal. Output signal. Connected to 1. Connected to 3. Stereophonic system. Input signal of left-hand channel. Output signal of left-hand channel. Input signal of right-hand channel. Output signal of right-hand channel. SCART CONNECTOR The Scart connector, also known as the Euroconnector or Peri-Television connector, is part of a system for connecting television receivers and other home entertainment equipment. A Scart connector has 21 pins which provide for stereo audio and composite video in and out, RGB, two data lines and two control lines. A variation allows for separate chrominance and luminance signals.. NOTES: 1. Pin 8 is used to select between an internal and external composite video signal. +12 volts applied to this pin will enable the composite video input on pin 20. Alternatively, this input may be enabled via a control on the video display device, e.g. an external AV select switch. 2. Pin 16 is a control line to select the external RGB inputs. +3 volts applied to this pin enables the RGB inputs on pins 15, 11 and 7. 3. When used for S-VHS signals, pin 15 carries chrominance and pin 20 luminance. 4. Pin 10 and 14 have been assigned for data for controlling and monitoring other appliances.. PIN 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21. USE Audio Output (R) Audio Input (R) Audio Output (L) Audio Ground Blue Ground Audio Input (L) Blue Status (CVBS) Green Ground Data D2B (Inverted) Green Data D2B Red Ground D2B Ground Red RGB Status/Fast Blanking CVBS Video Ground RGB Status Ground Composite Video Output Composite Video Input Case/shield. Step 1. Cut end of cable evenly and remove 22mm of outer sheath.. Step 2: Remove 16mm of braid and dielectric, taking care not to damage centre conductor. Lightly tin conductor.. Step 3: Slide cap and collet clamp over cable and slightly squeeze collet in position. Comb braid out and fan back over collet.. Step 4: Solder tip of plug to centre conductor. Do not overheat. Push sub-assembly into body of plug, and screw cap onto body to complete assembly.. 402. Step 1: Cut end of cable evenly and remove 8mm of outer sheath. Step 2: Slide clamp nut and pressure sleeve over cable, and comb out braid. Step 3: Fold braid back and insert ferrule between braid and dielectric. Trim off excess braid. Step 4: Remove 5mm of dielectric without damaging centre conductor. Tin conductor. Step 5: Slide rear insulator over conductor hard against rear insulator. Solder contact to conductor.. BNC TYPE (MALE). Step 1: Cut end of cable evenly, and remove 7mm of outer sheath.. Step 2: Slide clamp-nut, washer and rubber spacer over cable. Slide pressure sleeve over braid, and fan out braid. Step 3: Fold back braid against pressure sleeve and trim off excess. Strip 4mm of inside insulation off centre wire. Solder pin onto centre wire.. Step 4: Fit assembly, pin first, into main receptacle. Push Step 6: washer, rubber spacer and clamp Fit front insulator in body and push nut up and screw sub-assembly onto body. Slide into place. pressure sleeve into body and screw in the clamp nut to clamp cable.. see the full range at www.dse.com.au. Earth/Shield Out of Phase In Phase. 1 3. HEADPHONE PLUG. S-VIDEO CONNECTOR. 0.5V/10kΩ 0.7Vp-p/75Ω L: 0-2V H: 10-12V/10kΩ 0.7Vp-p/75Ω. YAESU 8-PIN MICROPHONE. 0.7Vp-p/75Ω L: 0-0.4V H: 1–3V/75Ω 1V/75Ω 1V/75Ω. ‘N’ TYPE. Step 1: Cut end of cable evenly and remove 9mm of outer sheath. Step 2: Slide clamp nut and pressure sleeve over cable, and comb out braid. Step 3: Fold braid back and insert ferrule between braid and dielectric. Trim off excess braid and remove 5.5mm dielectric without damaging inner conductor. Tin end of conductor. Step 4: Slide rear insulator over conductor and position against end of dielectric. Slide contact over conductor until hard against rear insulator. Solder contact to conductor. Step 5: Fit front insulator in body and push sub-assembly into body. Slide pressure sleeve into body and screw in the clamp nut to clamp cable.. 1. 2. 3.. LEVEL/IMPEDANCE 0.5V/1kΩ 0.5V/10kΩ 0.5V/1kΩ. Commonly used on base and mobile transceivers. GET IT RIGHT!. WIRING RF PLUGS BNC TYPE (FEMALE). COMMON ALTERNATIVE. Earth/Shield In Phase (hot) Out of Phase (cold). 2. Monaural system. BELLING-LEE TYPE. IEC STANDARD. 1. 2. 3.. Hot lead of right-hand channel. Monaural system Stereophonic system. Widely used in professional audio applications these connectors generally offer a locking mechanism, very good cable clamping and low contact resistance. The pins are arranged so that when the connectors mate, one pin (used as the ground pin) always makes contact before the other two.. UHF TYPE. Note the locations of the Active, Neutral and Earth pins, and their associated wire colours in the table below. If you are replacing a mains plug or socket on an extension cord, then follow exactly the wiring instructions supplied with the mains plug or socket.. Step 1: Cut end of cable evenly and remove 27mm of outer sheath. Step 2: Slide coupling ring and adaptor onto sheath. Fan braid back over sheath.. PLUG Neutral. Plug. Step 3: Compress braid around cable and position adaptor so braid fans over adaptor. Trim off excess braid.. Step 4: Remove 12.5mm dielectric and tin conductor. Screw the plug assembly onto cable and solder plug to braid through solder holes.. Active. Earth. SOCKET. Neutral. Earth. Active. COLOUR CODE TABLE Step 5: Solder conductor to centre pin and screw coupling ring onto assembly.. CONDUCTOR Active Neutral Earth. COLOUR Brown Blue Green/Yellow. OLD COLOUR Red Black Green.
Related documents