U! QGK| INT! . 3MHZ |0.2V/uS| +18V{-18V| 85C| 88dB | 6MV [200NA | SONA|SOOMWF) SMA | 12| 18V| 36V 1MA | 70dB | 77dB |800K AMLW249D ADU] QGK| INT} 1MHZ/0.5V/uS| +18V]-18V] 85C |} 88dB} GMV |200NA | SONA/SOOMHF) SMA; 12V| 18V) 36V . 1MA | 70dB } 77dB |800K AMLM301AD = | ADU) GPU) EXT +18V|-18} 70C | 88dB |7.5MV |250NA | SONA|SOOMWF} SMA] 12V/ 15} 30V} 30uv/C 3MA | 70dB;, 7008 SOCK AMLM3014H = | ADU! GPU] EXT +18V|-18V] 70C | 88dB |7.5MV [2SONA | SONA|SOOMWF| SMA] 12V) 15V| 30V} 30uV/C 3MA | 7008 | 70dB |SOOK AMLM301AN ADU! GPU! EXT +18V{-18V| 70C | 88dB |7.5MV 2SONA | SONA) SOOMWF| SMA! 12V| 15V| 30| 30uv/C 3MA | 700B | 70dB [500K AMLM3010 ADU! GPU] EXT 4+18V|-18V] 70C|} 83dB) 1OMV} 2uA|.7SuUA|SOOMWF| SMA] 12V} 15V; 30V) 30uV/C 3MA | 65dB} 70dB |100K AMLM301F ADU) GPU} EXT +18V)-18) 70C; 83dB} 1OMV} 2uA).75uA) 12V} 15} 30) 30uV/C 3MA ) 650B ) 70dB )L00K AMLM301H ADU} GPU] EXT +18V/-18V) 70C/ 83dB]) 1OMV} 2uA|.75UA|SOOMMF] . 12V| 15SV] 30| 30uv/C 3MA | 65dB | 70dB |100K AMLM302D ADU] VF
3 E-4 E+4G R3 MLM239L. LM239D 0} AMLM239D DIL-14/1C]R1 | E-L} E+1] V+ | +2 R2 |R3 E+3 V~ | E+4 R4 . LM248D 0} AMLM248D DIL-14/1P}R1 | E-1}E+1) + | E+2 R2 }R3 E+3 V~ | E+4 R4 : LM249D 0} AMLM249D DIL-14/1P\FT | E- JE+ | V- |T* V+ |F* TDAO301D | LM301AD 0} AMLM301AD TO5-8/1M |FT | E- | E+ |) -M] T* y+ |F* SFC2301AH | LM301AH 0} AMLM301AH DIL-8/1P |FT |E- |E+ |V- |T* V+ | F* -fo. do. . SFC2301 ADC] LM301AN Q} AMLM301AN DIL-14/1P)N |N | FT |E- | E+ N IN R | V+ | F* N LM301D | AMLM3010 FLP-10/3C]N |FT |E- |E+ | V- R | V+ N : LM301F 0} AMLM301F TO5-8/1M {FT | E- | E+ | -M}T* y+ {F* . . . : SFC2301A | LM301H 0} AM_LM301H DIL-14/1C)N JN JT JN JE+ N IN R | V+ | T* N : LM302D 0} AMLM302D TOS-8/1M |T {N JE+ |V- GL V+ |T* UA302C LM302H 0} AMLM302H TO5-8/1M |G |E+ | E- | -M/S1 R | + . . [| - : SN72306L | LM306H 0] AMLM306H DIL-14/1P|N |N |N JE- |E+ N IN R | V+ IN N SN72307JA | LM3070 0} AMLM307D T05-8/1M JN |E~ | E+ | V-MIN V+ IN re : SFC2307 LM307H 0} AM_LM307H DIL-14/1PIN |}F JN JE
3 E-4 E+4G R3 MLM239L. LM239D 0} AMLM239D DIL-14/1C]R1 | E-L} E+1] V+ | +2 R2 |R3 E+3 V~ | E+4 R4 . LM248D 0} AMLM248D DIL-14/1P}R1 | E-1}E+1) + | E+2 R2 }R3 E+3 V~ | E+4 R4 : LM249D 0} AMLM249D DIL-14/1P\FT | E- JE+ | V- |T* V+ |F* TDAO301D | LM301AD 0} AMLM301AD TO5-8/1M |FT | E- | E+ |) -M] T* y+ |F* SFC2301AH | LM301AH 0} AMLM301AH DIL-8/1P |FT |E- |E+ |V- |T* V+ | F* -fo. do. . SFC2301 ADC] LM301AN Q} AMLM301AN DIL-14/1P)N |N | FT |E- | E+ N IN R | V+ | F* N LM301D | AMLM3010 FLP-10/3C]N |FT |E- |E+ | V- R | V+ N : LM301F 0} AMLM301F TO5-8/1M {FT | E- | E+ | -M}T* y+ {F* . . . : SFC2301A | LM301H 0} AM_LM301H DIL-14/1C)N JN JT JN JE+ N IN R | V+ | T* N : LM302D 0} AMLM302D TOS-8/1M |T {N JE+ |V- GL V+ |T* UA302C LM302H 0} AMLM302H TO5-8/1M |G |E+ | E- | -M/S1 R | + . . [| - : SN72306L | LM306H 0] AMLM306H DIL-14/1P|N |N |N JE- |E+ N IN R | V+ IN N SN72307JA | LM3070 0} AMLM307D T05-8/1M JN |E~ | E+ | V-MIN V+ IN re : SFC2307 LM307H 0} AM_LM307H DIL-14/1PIN |}F JN JE
. . MLW3OLAG MTU! GPU; EXT +18V|-18V! 75C | 88dB (7. SMV (250NA | SONA |SOOMWF) SMA) 12i; 15i 30) 3Guv/C 3M | 7008) 70dB \0.5M MLM301 AP1 MTU} GPU EXT +18V|-18V| 75C | 88dB 17.5MV |250NA | SONA /62SMWF) SMA | 12V{ 15V| 30V; 30uV/C 3MA | 70dB | 70dB j0.5M MLM301AU MTU| GPU} EXT +18V|~18V 75C | 88dB 7. SMV (250NA | SONA |625MWF} SMA | 12V] 15V) 30V | 30uV/C 3MA | 70dB | 70dB \0. 5M MLM307G MTU! GPK] INT +18V/-18V| 70C | 880B /7.SMV 250NA | SONA|SOOMWF] SMA] 11 15V] 30V! 30uV/C 3MA | 70dB | 70dB |0. SM MLM307P1 MTU] GPK] INT +18V|-18V] 70C } 88dB |7.SMV |250NA | SONA|SOOMWF) SMA] 12V| 15] 30V/ 30uVv/C 3MA | 70dB | 70dB 0. 5M MLM307U MTU! GPK | INT +18 |-18 |70C | 880B (7.5MV 250NA SONA |SOOMWF) SMA) 12V; 15V; 30V| 30uV/C 3MA | 70dB | 70dB |0.5M MLM308AF MTU) LBC) EXT +18V)-18) 70C | 98dB O.5MV) JNA) INA{SOOMWF} IMA) 13V) 15V) iV} SuV/C .6MA | 960B | 96dB } 10M MLM308AG MTU} LBC | EXT +18V|-18V| 70C | 98dB j0.5MV} 7NAj INA|SOOMWF] IMA] 13V] 15V; 1lV{ SuV/C .6MA | 960B | 96dB/ 10M MLM308AP1 MTU] LBC
U! QGK| INT! . 3MHZ |0.2V/uS| +18V{-18V| 85C| 88dB | 6MV [200NA | SONA|SOOMWF) SMA | 12| 18V| 36V 1MA | 70dB | 77dB |800K AMLW249D ADU] QGK| INT} 1MHZ/0.5V/uS| +18V]-18V] 85C |} 88dB} GMV |200NA | SONA/SOOMHF) SMA; 12V| 18V) 36V . 1MA | 70dB } 77dB |800K AMLM301AD = | ADU) GPU) EXT +18V|-18} 70C | 88dB |7.5MV |250NA | SONA|SOOMWF} SMA] 12V/ 15} 30V} 30uv/C 3MA | 70dB;, 7008 SOCK AMLM3014H = | ADU! GPU] EXT +18V|-18V] 70C | 88dB |7.5MV [2SONA | SONA|SOOMWF| SMA] 12V) 15V| 30V} 30uV/C 3MA | 7008 | 70dB |SOOK AMLM301AN ADU! GPU! EXT +18V{-18V| 70C | 88dB |7.5MV 2SONA | SONA) SOOMWF| SMA! 12V| 15V| 30| 30uv/C 3MA | 700B | 70dB [500K AMLM3010 ADU! GPU] EXT 4+18V|-18V] 70C|} 83dB) 1OMV} 2uA|.7SuUA|SOOMWF| SMA] 12V} 15V; 30V) 30uV/C 3MA | 65dB} 70dB |100K AMLM301F ADU) GPU} EXT +18V)-18) 70C; 83dB} 1OMV} 2uA).75uA) 12V} 15} 30) 30uV/C 3MA ) 650B ) 70dB )L00K AMLM301H ADU} GPU] EXT +18V/-18V) 70C/ 83dB]) 1OMV} 2uA|.75UA|SOOMMF] . 12V| 15SV] 30| 30uv/C 3MA | 65dB | 70dB |100K AMLM302D ADU] VF
DVM shows application Fig. 3 shows how the technique can be incorporated into a 2-1/2-digit digital voltmeter. The circuit uses the staircase type of conversion, with the staircase being produced by the 2-1/2- digit BCD-coded D/A and the BCD counters. The MLM301A4 is used as a comparator to compare the staircase to the input signal.
must be compensated for unity gain, and in some cases overcompensation may be desirable. Note that this configuration results in a positive output voltage anly, the magnitude of which is dependent on the digital input. The following circuit shows how the MLM301AG can be used in a feedforward mode resulting in a full scale settling time on the order of 2.0 ys. FIGURE 18 (To pina of MC1508L8) An alternative method is to use the MC1539G and input com- pensation. Response of this circuit is also on the order of 2.0 us. See Motorola Application Note AN-459 for more details on this concept. FIGURE 19 +15 e (To pina of MC1508L8) 240 O02 uF The positive voltage range may be extended by cascading the output with a high beta common base transistor, Q1, as shown. FIGURE 20 EXTENDING POSITIVE VOLTAGE RANGE (Resistor and diode optional see text) Ge The output voltage range for this circuit is 0 volts ta BVcBO of the transistor. If pin 1 is left open, the transistor base may be graunded, eliminating both the
must be compensated for unity gain, and in some cases overcompensation may be desirable. Note that this configuration results in a positive output voltage only, the magnitude of which is dependent on the digital input. The following circuit shows how the MLM301AG can be used in a feedforward mode resulting in a full scale settling time on the order of 2.0 us. FIGURE 18 65 pF (To pind of MC1508L8} An alternative method is to use the MC1539G and input com- pensation. Response of this circuit is also on the order of 2.0 us. See Motorola Application Note AN-459 for more details on this concept. FIGURE 19 +15 V@ 35 oF It iw 5k w-$4 7 10k 'o 2 8 (To pind _ 6 4 MC1508L8) o 3 |Mcis396 Vo 240 + 8 o2 ue a! tok 2200 oF = 1sv The positive voltage range may be extended by cascading the output with a high beta common base transistor, Q1, as shown. FIGURE 20 EXTENDING POSITIVE VOLTAGE RANGE (Resistor ana diode optional see text) Ge The output voltage range for this circuit is 0 volts to BYVcBO of the transisto
must be compensated for unity gain, and in some cases overcompensation may be desirable. Note that this configuration results in a positive output voltage only, the magnitude of which is dependent on the digital input. The following circuit shows how the MLM301AG can be used in a feedforward mode resulting in a full scale settling time on the order of 2.0 us. FIGURE 18 65 pF (To pind of MC1508L8} An alternative method is to use the MC1539G and input com- pensation. Response of this circuit is also on the order of 2.0 us. See Motorola Application Note AN-459 for more details on this concept. FIGURE 19 +15 V@ 35 oF It iw 5k w-$4 7 10k 'o 2 8 (To pind _ 6 4 MC1508L8) o 3 |Mcis396 Vo 240 + 8 o2 ue a! tok 2200 oF = 1sv The positive voltage range may be extended by cascading the output with a high beta common base transistor, Q1, as shown. FIGURE 20 EXTENDING POSITIVE VOLTAGE RANGE (Resistor ana diode optional see text) Ge The output voltage range for this circuit is 0 volts to BYVcBO of the transisto
emperature Range (0C to +70C) MC1439 High Slew Rate 1 7.5 15 100 16K 2 4.2 +6 +18 601, 626, Op Amp 632, 646 MC1709C General Purpose 1.5 75 45 500 15K 1 3 +3 +18 601, 606 Op Amp 626, 632 MC1748C General Purpose 5 6 15 200 20K 1 5 +3 +18 601, 626 Op Amp 693 MLM301A ] General Purpose 625 75 10 50 25K 1 5 +3 +18 601, 626 Op Amp 693 MLM308A J Precision Op Amp 7 5 5 1 80K 1 3 +3 +18 601, 606 626, 693 MLM308 Precision Op Amp 7 7.5 15 1 25K 1 3 +3 +18 601, 606 A. A. RK DEE A. A. KAS 88 DUAL OPERATIONAL AMPLIFIERS INTERNALLY COMPENSATED YY 8 VIO BW (Av 1) SR (Av=1} Supply Voltage f | mV MHz Vius Device Description max rnax typ typ min/typ max/typ Packages Military Temperature Range (55C to 428C) MC1558 Dual MC1741 10 200 50 K 1.1 es) +3 +22 601, 632 Op Amp 693 MC1558N Dual Low Noise 5 5 10 200 50 K 1.1 8 +3 +22 601, 632 Op Amp 693 MC1558S | High Slew Rate 5 5 10 200 50K 1 10 3 +22 601, 632 Dual Op Amp 693 MC1747 Dual MC1741 5 5 10 200 50 K 1 5 +3 +22 601, 632 Op Amp MC3558 Single Supply 5 5 10 50 50 K 1 6