Control de la temperatura i el llum
 U V : С Universitat de Vic
Escola Politécnica
Superior
Treball Final de Grau
Control de la temperatura i el llum
mitjangant dispositius sense fils
DATASHEET
ШУ! С Universitat de Vic Control de la temperatura i el llum mitjangant dispositius sense fils
Escola Politécni |
Superior ces Ramon Altarriba Roca
INDEX
RELE
LDR VT900
SENSOR TEMPERATURA
REGULADOR DE TENSIÓ
OPTOACOBLADOR
AMPLIFICADOR OPERACIONAL
LCD GDM1602K
ARDUINO ETHERNET
ARDUINO USB2SERIAL
XBEE SHIELD
XBEE EXPLORER
XBEE
ШУ! С Spd Control de la temperatura i el lum mitjangant dispositius sense fils
Superior Ramon Altarriba Roca
RELÉ
34
Bas 34 Series - Slim solid state PCB relays (SSR) 0.1 -2 A
_ Features 34.81-9024 34.81-7048 34.81-8240
| Ulrro-slim - Solid Stote Relays
A A Printed circuit mount
director via PCB socket
35 mm rail mount
- via screw, sarewless or push-in terminal sockets|
e Single circuit output switching options
-2 A 24VDC
-0.1A 48VDC
-2 A240VAC
e Silent, high speed switching with long «2 A, 24 V DC output «0.1 A, 48 V DC output « 2 À, 240 V AC output switching
RE ETS switching switching e Zero crossing switching
e PCB or 93 series sockets « PCB or 93 series sockets « PCB or 93 series sockets
o Ultra slim, 5 mm, package
+ Sensitive DC Input circuits (Dual AC/DC
input drive possible using 93 series sockets) à | co
« UL Listing {certain relay/socket combinations) : [= Y г | ; [= 4, р | i | Es ” T |!
e Wash tight: RTM] AO. net | 199... z
e 2,500 Y insulation, inputoutput Az At n+ 14 KE Alt ig 1s Az Ai пом
- - - - = ||
e "a М "a output
13 13
A PAE рая
| az 16.25 5 | 19 =! lb] 16.25 EN RE
La 28 > | 28 A
For outline drawing see page 5 Copper side view Copper side view Copper side view
Output circuit
Contact configuration 1 NO (SPST-NO) 1 NO (SPST-NO) 1 NO (SPST-NO)
Rated current/Maximum peak current {1 O ms) Al o 2/20 Ш 0.1/0.5 2/40 —
Rated voltage/Maximum blocking vollage — Y [24/33)DC (48/60)DC [240/—)AC
Switching voltage range у [1.5...24)DC [1.5...48)DC (12...275)AC
Repetitive peak offstate voltage - a Vek — — 600 |
Minimum switching current mA 1 0.05 22
Max. “OFF-state” leakage current mA 0.001 0.001 1.5
Max, “ON-state” voltage drop у 0.12 1 1.6
input circuit
Nominal voltage VDC| 5 | 12 24 60 24 60 5 12 24 60
‘Rated power AC/DC w]|o0.035/0087| 0.17 [018] 017 | 018 0.060 | 0.087 | 0.17 | 0.18
Operating range V DC|3.5...12 8.17 16...30|35..72| 16.30 35.72 |3.5...10| 8.17 |16...30|35..72
Control current mAl 7 7.2 7 3 7 3 12 7.2 7 3
Release voltage VDC| 1 4 10 20 10 20 1 4 10 20
Impedance &| 715 , 1,940 13,200 21,300 3,200 21,300 416 | 1,940) 3,200 (21,300
Technical data
Operate/release time ms 0.1/0.6* | 0.04/0.6* 12/12*
Dielectric strength between input/output V 2,500 2,500 Ш 2,500
Ambient temperature range °C —20...+60 —20...+60 —20...+60
Environmental protection RT II КТ RT lil
Approvals [according 19 pa CES MES Ma CES Mu
* Note: all technical data relates lo using the relay directly on PCB or PCB socket type 93.11.
If the relay is used with 35 mm rail socket type 93.51, refer to the technical data of 38 Series; if used with types 93.60, 93.61, 93.62, 93.63,
93.64, 93.65, 93.66, 93.67,93.68 and 93.69, refer to the technical data of the MasterINTERFACE 39 Series.
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Features 34.51
Ultra-slim 1 Pole - 6 A relay |
Printed circuit mount A
- direct or via PCB socket DD
35 mm rail mount
- via screw, screwless or push-in terminal sockets
« 1 Pole changeover contacts or
1 Pole normally open contact
« Ultra slim, 5 mm, package
» Sensitive DC coil - 170 mW [Dual AC/DC coil
d ibl à . «5 mm wide
rive possible using 93 series sockets) Low coil
- Low coil power
* UL Listing (certain relay/socket combinations) |, pcs or 93 series sockets
+ Cadmium Free contact materials
» 8/8 mm clearance/creepage distance
+ 6 kV {1.2/50 ps) insulation, coilcontacts peorman ona еее ı
AZ Al 12 11 14
1 13
balla | — —— ]]———] '
firs 2: ¢ Pa of
8 11,25 | 5; 5,/|,19
28
FOR UL RATINGS SEE:
“General technical information” page V
For outline drawing see page 5 Copper side view
Contact specification
Contact configuration 1 CO (SPDT)
Rated current/Maximum peak current A 6/10
Rated voltage/Maximum switching voltage Y AC 250/400
Rated load ACT VA 1,500
Rated load ACT5 (230 V АС} VA 300
Single phase motor rating (230 V AC) kW 0.185
Breaking capacity DC1: 30/110/220 Y A 6/0.2/0.12
Minimum switching load mW [V/mA) 500 (12/10)
Standard contact material AgNi
Coil specification
Nominal voltage (UN) V AC [50/60 Hz) = |
V DC 5-12-24-48-60
Rated power AC/DC VA (50 Hz)/W —/0.17
Operating range AC —
DC (07... 1.5)UN
Holding voitage AC/DC —/0.4 UN
Must drop-out voltage AC/DC —/0.05 UN
Technical dota
Mechanical life AC/DC | cycles —/10 - 10°
Electrical life at rated load ACT cycles 60 - 10°
‘ Operate/release time. ms - 5/3
5 Insulation between coil and contacts [1.2/50 ps} kV 6 {8 тт}
£ Dielectric strength between open contacts V AC 1,000
= Ambient temperature range °C -40...+85
E Environmental protection RT Il
xt
© rovals [according to type :
8 Approvals ( g fo type) E NL E RNA Ads D
34 Series - Ultra-Slim PCB relays
Ordering information
Eleciromechanical relay (EMR
Example: 34 series slim electromechanical relay, 1 CO [SPDT) ó A contacts, 24 Y sensitive DC coil.
A B C D
| :
3 4.05//1.7.10 2 4..0//0/|1:/0:
- | | a I |
Series ——— A: Contact material D: Special versions
т О = Standard AgNi 0 = Flux proof [RT Ii}
ype 4 = AgSnQO, 9 = Flat version
5 = Electromechanical type 5 _ AcNi + Au
No. of poles | 9 — C: Opfions
° B: Contact circuit | = None
1=1 pole, 6 A 0 = CO (SPDT)
Coil version 3 = NO [SPST]
7 = Sensitive DC
Coil voltage
See coil specifications
Selecting features and options: only combinations in the same row are possible.
Preferred selections for best availability are shown in bold.
Type |Coil version | A B С D
34.51 |sens. DC 0-4-5 |0-3 1 0
34.51 |sens. DC 0-4-5 |0 1 9
Solid state relay (SSR)
Example: 34 series SSR relay, 2 A output, 24 Y DC supply.
A DS: —_ —
34.08 1,7.|0 2 4.902 |
Series _ | || оно circuit
| 9024 = 2A- 24VDC
Type
7048 = 0.1 A- 48YDC
8 = SSR type 8240 = 2 А-240 \ АС
oom
1=1 NO (SPSTNO)
Input circuit |
See input specifications
Flat pack version
Ton
| 28
15
15.6
611;
T
CU | +1
{x |
Option =34.51.7xxx.x019 qz 7;
Environmental protection RT | | |
3.75 КЕ | 5 | 1.9
Copper side view
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34 Series - Ulira-Slim PCB relays
Electromechanical relay
Technical data
1\! Insulation according fo EN 618101
| Nominal voltage of supply system VAC | 230/400 N
I - Rated insulation voltage Y AC | 250 400
Pollution degree mu 3 2 _
Insulation between coil and contact set ©
Type of insulation Reinforced
Overvoltage category || _
Rated impulse voltage kV [1.2/50 ps) | 6
Dielectric strength V AC | 4,000
Insulation between open contacts
Type of disconnection a | Micro-disconnection a
Dielectric strength V AC/kV (1.2/50 ps) | 1,000/1.5
Conducted disturbance immunity
Burst (5...50)ns, 5 kHz, on Al - A2 EN 61000-4-4 level 4 {4 kV)
Surge (1.2/50 ps) on Al - A2 (differential mode) TEN 61000-4-5 level 3 (2 kV)
Other data
Bounce time: NQ/NC ms | 1/6
Vibration resistance (5...55)Hz: NO/NC ~~ g | 10/5 — _ LL
‘Shock resistance 120/14 I -
Power lost to the environment without contact current W | 0.2 a
with rated current W | 0.5 о
Recommended distance between relays mounted on PCB тт | = 5 |
Contact specification
F 34 - Electrical life (AC) v contact current H 34 - Maximum DC1 breaking capacity
107 20
< 1
10° 5
$ 3 2
5 Ëê 1
10° 5
=
e 0.2
10° 0.1
20 60 100 140 180 220
[A] DC voltage [Y]
* When switching a resistive load (DC1) having voltage and current
values under the curve, an electrical life of > 60-10? can be expected.
* In the case of DC13 loads, the connection of a diode in parallel with
the load will permit a similar electrical life as for a DC1 load.
Note: the release time for the load will be increased.
Coil specifications
1 - Max. permitted coil voltage.
2 - Min, pick-up voltage with coil at ambient temperature.
DC coil data R 34 - DC coil operating range v ambient temperature
Nominal | Coil Operating range — | Resistance | Rated coil U
voltage code consumption Un 2.0
UN Uniin Umox R Iat Uy
Vv \у Y Q | mA
5 ! 7005 | 35 1 75 130 | 38.4 15
12. 7.012 8.4 | 18 840 | 14.2
24 | 7024 | 168 | 36 |! 3350, 7. i.
48 | 7.048 33.6 | 72 12,300 | 39 E
60 | 7.060 | 42 90 19700! 3 $
0.5 $
-20 0 20 40 60 80 =
PC) $
=
&
>=
A finder
Solid state relay
Technical data
EMC specifications : Reference standard
Electrostatic discharge contact discharge | EN 61000-4-2 4 kV
air discharge EN 61000-4-2 8 kV
Fast transients on supply terminals = = ET
(burst 5/50 ns, 5 kHz) EN 61000-4-4 2 kv
Voltage pulses on supply common mode EN 61000-4-5 0.5 kV
terminals [surge 1.2/50 ps) differential mode | EN 61000-4-5 0.5 kV
Other data
Power lost to the environment without output current W | 0.17
with rated current W | 0.4
Input specification
Input data - DC types
Nominal | Input Operating range Release |Impedance | Control
voltage code voltage current
UN Unin Umax Tat Uy
Y | Y у \ Q mA
5 7.005 35 [12.10%] 1 |715 (416*)| 7 [12*)
12 7.012 8 17 4 1,940] 7.2
24 | 7024 | 16 | 30 | 10 | "3200 7
60 | 7.060 35 | 72 20 | 21,300] 3 _
* AC Output version.
Output specification
L 34 - Output current v ambient temperature
SSR - 2 À DC & AC output types
L 34 - Output current v ambient temperature
SSR - 0.1 À DC output types
3.5
3.0 0.15
пра 2.5 —
= =
Ё 5
5 20 5 0.10
= >
a 15 3
= =
O 1.0 O 0.05
0.5
0.0 0
20 O 20 40 60 80 100 20 O 20 40 6&0 80 100
(°C) PO]
Ouiline drawings
Type 34.51 Type 34.81
28 5 28 5
1 — 4, Y
= 5
o T—
+ 1 y (Е || cu]
un o
0.5 х 0.5 | | 1х 0.4 e es
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93 Series - Sockets and acce
Common features
- Space saving 6.2 mm wide
- Connections for 16-way jumper link
- Dual screw head [blade+cross) terminals
ssories
Lu
- Integral coil indication and protection circuit
- Secure refention and easy ejection by plastic clip
Electromechanical Relay - EMR
for 34 series relays Re
= D finder
Screw terminal socket 35mm rail mounting (EN 60715) a
For technical data and supply versions, refer to the MasterINTERFACE 39 Series — “Relay interface module”
Socket type {reference w with the 39 Series)
Supply voltage Relay type — | MasterBASIC | MosterPLUS | MasterINPUT : MasterOUTPUT| MasterTIMER
1 (3911) | (3931...) | 13941...) ! 139.21 J] [39 81...)
6 V AC/DC 34.51.7.005.xx10 | 93.61.7.024 | 93.63.7.024 | 93.64.7.024 | 93.62.7.024 —
12V AC/DC” |34.51.7.012.xx10193.61.7.024 | 93.63.7.024 | 93.64.7.024 | 93.62.7.024 | 93.68.0.024
24 V AC/DC | 34.51.7.024.x10 |93.61.7.024 | 93.63.7.024 | 93.64.7.024 | 93.62.7.024 | 93.68.0.024
60 V AC/DC | 34.51.7.060.xx10 — 93.63.7.060 — — =
(110...125V AC/DC*| 34.51.7.060.xx10 — 93.63.3125 — — =
(220...240)V AC* | 34.51.7.060.xx10 = 93.63.3.230 = = = —
[110...125)V AC/DC | 34.51.7.060.xx10 | 93.61.0.125| 93.63.0.125 | 93.64.0.125 | 93.62.0.125 | —
[220...240)V AC | 34.51.7.060.xx10 | 93.61.8.230 | 93.63.8.230 | 93.64.8.230 | 93.62.8.230 —
(110...125) VDC | 34.51.7.060.xx10 — 93.63.7.125 = — В
220 V DC 34.51.7.060.xx10 — 93.63.7.220 = — В
* Leakage current suppression
Solid State Relay - SSR
= E * Socket type [reference with the 39 Series)
o Supply voltage Relay type — | MasterBASIC | MasterPLUS | MasterINPUT | MasterOUTPUT| MosteTIMER
E : {3910 } | (3930 ) | (3240. } | (39220...) | (39.80...)
ET 12VAC/DC | 34.81.7.012.00x | В — — — 93.68.0.024
24V AC/DC | 34.81.7.024.000 | В 93.63.0.024 | 93.64.0.024 | — 93.68.0.024
[110...125)V AC/DC*| 34.81.7.06000x | — |93.63.3.125 = = =
Approvals `(220...240)у АС* | 34.81.7.060 000 — [93633230 — [| = —
{according to type): [110...125)V AC/DC| 34.81.7.060.50xxx | 93.61.0.125 | 93.63.0.125 | 93.64.0.125 | 93.62.0.125 =
СЕ НГ @ Nu (220...240)V AC | 34.81.7.060.00x ! 93.618.230 | 93.63.8.230 | 93.64.8.230 | 93.62.8.230 | —
6 V DC 34.81.7.005 000 | 93.61.7.024 | 93.63.7.024 | 93.64.7.024 | 93.62.7.024 =
12VDC | 34.81.7.012.00x | 93.61.7.024 | 93.63.7.024 | 93.64.7.024 | 93.62.7.024| —
2AVDC — | 34.81.7.024.0x |93.61.7.024 | 93.63.7.024 | 93.64.7.024 | 93.62.7.024 =
TT 60VDC |34.81.7.060xx1 — [93637060] — | -— ==
(110...125 Y DC | 34.81.7.060.x00 | — |93.637.125 = i = =
— 220vDC 34.81.7.060.00x | — |93.687.220] — | — =
* leakage current suppression
Accessories
16-way jumper link 093.16 (blue), 093.16.0 [black], 093.16.1 (red)
Dual-purpose plastic separator 093.60
Sheet of marker tags 060.72
Technical data
Rated values | 6 A-250V
Dielectric strength LS |6 К (I. 2/50 ps) k ps) between coil and contacts
Protection | category Tro o
“Ambient temperature o °C | -40..470 a a
‘Screw torque oT Nm 0.5 ‘ a
Wire strip length | В mm | 10
| Solid wire and stranded wire
mm? 11 x(0.2...2.5)/2x1.5
AWG | 1x|24...14) / 2x 16
Max wire size
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Common features
- Space saving 6.2 mm wide
- Connections for 16-way jumper link
- Integral coil indication and protection circuit
- Secure retention and easy ejection by plastic clip
Electromechanical Relay - EMR
93 Series - Sockets and accessories for 34 series relays =)
34
Push-In terminal socket 35mm rail mounting (EN 60715) 55)
For technical data and supply versions, refer to the MasterINTERFACE 39 Series — "Relay interface module"
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Socket ?ype [reference with the 39 Series)
Supply voltage Relay type MasierBASIC | MasterPLUS | MasterINPUT | Master OUTPUT| MasterTIMER
(3901...) | 139961...) | [39.71 .) ! 3951) | (3991 |)
6 Y AC/DC 34.51.7.005.xx10 | 93.60.7.024 | 93.66.7.024 | 93.67.7.024 | 93.65.7.024 —
12 V AC/DC 34.51.7.012.xx10 | 93.60.7.024 | 93.66.7.024 | 93.67.7.024 | 93.65.7.024 | 93.69.0.024
24 V AC/DC 34.51.7.024.xx10 | 93.60.7.024 | 93.66.7.024 | 93.67.7.024 | 93.65.7.024 | 93.69.0.024
60 Y AC/DC 34.51.7.060.xx10 — 93.66.7.060 — — —
[110...125)V AC/DC*| 34.51.7.060.xx10 — 93.66.3.125 — — =
(220...2AO]V AC* | 34.51.7.060.xx10 | — 93.66.3.230 — — =
[110...125)V AC/DC | 34.51.7.060.xx10 } 93.60.0.125 | 93.66.0.125 | 93.67.0.125 | 93.65.0.125 —
[220...240)V AC | 34.51.7.060.xx10 | 93.60.8.230 | 93.66.8.230 | 93.67.8.230 | 93.65.8.230 mi
{11 10.. .125) Y \ DC 34.51.7.060.xx10 | — 93.66.7.125 — —
220YDC 34.51.7.060.xx10 | — 93.66.7.220 — — —
* Leakage current suppression
Solid State Relay - SSR
Socket type [reference with the 39 Series]
Supply voltage Relay type | MasterBASIC | MasterPLUS MasterINPUT ! Master OUTPUT MasterTIMER
i (3900... | (3960...) E [3970..1 ' (3950... J (3990
12 V AC/DC 34.81.7.012 xxx — — — — 93.69.0.024
24 Y AC/DC 34.81.7.024.хххх — 93.66.0.024 | 93.67.0.024 — 93.69.0.024
(110...125)v AC/DC*| 34.81.7.060.xxxx — 93.66.3.125 — — —
[220...240)V AC* | 34.81.7.060.xxxx — 93.66.3.230 — — =
(110...125}V AC/DC| 34.81.7.060.000 | 93.60.0.125 | 93.66.0.125 | 93.67.0.125 | 93.65.0.125 —
[220...240)V AC | 34.81.7.060.000 | 93.60.8.230 | 93.66.8.230 | 93.67.8.230 | 93.65.8.230 —
6 Y DC 34.81.7.005.хххх | 93.60.7.024 | 93.66.7.024 | 93.67.7.024 | 93.65.7024 —
— 12YDC 34.81.7.012.00 | 93.60.7.024 | 93.667.024 | 93.677.024 | 93.65.7.024 =
Approvals 24 V DC 34.81.7.024.xxxx | 93.60.7.024 | 93.66.7.024 |93.67.7.024 | 93.65.7.024| — —
[geserding 10 hype: 60VDC |34817060xox| — 93.66.7.060 — — =
CE ME Ns (110.125) VDC | 34817.06000x | — 9.667.125) — | —-— | —
220VDC | 34.81.7.060.00x — [93667220] — | — =
* Leakage current suppression
Accessories
16-way jumper link 093.16 (blue), 093.16.0 (black), 093.16.1 (redi
Duol-purpose plastic separator 093.60
Sheet of marker tags 060.72
Technical data
Rated values 6 A-250Y
Dielectric strength 6 kV (1.2/50 ps] between ceil and contacts
Protection category IP20
Ambient temperature °C | —-40...+70
Wire strip length mm | 8
Max wire size Solid wire and stranded wire
mm2 | 1 x (0.2...2.5)
AWG | 1x (24..14)
93 Series - Sockets and accessories for 34 series relays
0
Common features
- Space saving 6.2 mm wide
- Connections for 20-way jumper link
> - Integral coil indication and protection circuit
- Secure retention and easy ejection by plastic clip
93.51
Approvals
[according to type]:
CE ESAE Y
Screw less terminal socket 35mm rail mounting (EN 60715)
For technical data and supply versions, refer to the 38 Series — “Relay interface module”
RINA ¿As Electromechanical Relay - EMR and Solid State Relay - SSR
«(Ya Certain relay/ socket Relay type (reference with the 38 Series Ш
combinations Supply voltage Electromechnanica! relay - EMR| — Solid State Relay - SSR : Socket type
(38.61...) (38.81)
12 Y AC/DC 34.51.7.012.xx10 — 93.51.0.024
24 V AC/DC 34.51.7.024.xx10 — 93.51.0.024
a (110...125)V AC/DC 34.51.7.060.xx10 34.81.7.060.3000x 93.51.0.125
(220...240)V AC/DC 34.51.7.060.xx10 34.81.7.060. 00x 93.51.0.240
(110...125)V AC/DC * 34.51.7.060.xx10 34.81.7.060.00x 93.51.3.125
[220...240)V AC * 34.51.7.060.xx10 34.81.7.060.хххх 93.51.3.240
“1220...240)V AC 34.51.7.060.xx10 34.81.7.060.00x 93.51.8.240
12V DC 34.51.7.012.xx10 34.81.7.012.00x 93.51.7.024
24 Y DC 34.51.7.024.хх 10 34.81.7.024 xxxx 93.51.7.024
60 V DC 34.51.7.060.xx10 34.81.7.060.хххх 93.51.7.060
* Leakage current suppression
Accessories
20-way jumper link 093.20
"Plastic separator a —| 093.01
“Sheet of marker tags a 093.64 a a
Technical data
Rated values 6A-250V
Dielectric strength
6 kV [1.2/50 ps) between coil and contacts
Protection category
P20
Ambient temperature (Un< 60 V/> 60 V) °C
—40...+70/-40...+55
Wire strip length mm | 10
Max wire size Solid wire and stranded wire
mm? | 1x2.5/2x1.5
AWG | 1x14/ 2x16
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93.11
Approvals
[according to type):
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E NN E Ps
93 Series - Sockets and accessories for 34 series relays
e
SERIES
PCB socket with retaining and release clip 93.11 (blue;
For relay type 34.51, 34,81
Technical data
Rated values 6 A - 250 V
Dielectric strength >= 6 kV (1.2/50 ps) between coil and contacts
IP 20
Protection category
Ambient temperature
Retaining and release clip use:
°C | -40...+70
y
"ms mm Erm Em
"mE mE EEE Em
"ms mm EERE Em
HE + ¥ 0 4 JW am
Нин в т ини тя
ня ви ни ив ия
LL A A
"mm Frm EE EEE
"1..."
"..=...=."=
Wh JU
А? Ал 12 11 14
UV] C Universitat devi Control de la temperatura ¡ el llum mitjangant dispositius sense fils
Superior Ramon Altarriba Roca
LDR VT900
Photoconductive Cell VT900 Series
PACKAGE DIMENSIONS inch (mm)
_ 144 (3.56) 070 (1.78) | Ш 1.38 (35.05
164 (4.17) .090 (2.29) 1.62 (41.15) AWE 24 TINNED
COPPER LEADS
Er 7 т a
m 1721437 В 090 (2.29)
‚192 м 88) ; ‚110 (2.78)
PLASTIC COATED TO LEAD DIA. & PLASTIC COATING
PROTECT ACTIVE SURFACE NOT CONTROLLED WITHIN .10 (2.5)
OF CERAMIC SUBSTRATE
ABSOLUTE MAXIMUM RATINGS
Parameter Symbol Rating Units
Continuous Power Dissipation Py 80 mW
Derate Above 25°C APp/ AT 1.6 mW/ °C
Temperature Range
Operating and Storage Ta —40 to +75 °C
ELECTRO-OPTICAL CHARACTERICTICS @ 25°C (16 hrs. light adapt, min.) El
Resistance (Ohms) HEA Sensitivity |
10 lux 2fc Dark (У UP nep) CS
2850 K 2850 K ;
Fa Material "Voltage
Number Type we но. (М; рю)
Min. Typ. Max. Typ. Min. sec, Rise (1-1/e) | Fall (1/8)
VT9ON1 6k 12k 18k 6 k 200k 5 2 0.80 100 78 8
VT9BN2 12k 24 k 36 k 12k 500 k 5 D 0.80 100 78 8
VTIGNS 25 k 50 k 75k 25 k 1M 5 o 0.85 100 78 8
VT9ON4 50 k 100 К 150 К 50 k 2M 5 о 0.90 100 78 8
VT93N1 12k 24 k 36 k 12k 300 k 5 3 0.90 100 35 5
VT93N2 24 k 48 k 72k 24 k 500 k 5 3 0.90 100 35 5
VT93N3 50 k 100 К 150 К 50 К 500 К 5 3 0.90 100 35 5
VT93N4 100 k 200 k 300 k 100 k 500 k 5 3 0.90 100 35 5
VT935G
Group À 10k 185k 27 К 93k 1M 5 3 0.90 100 35 5
Group B 20k 29k 38 k 15k 1M 0.90 100 35 5
Group C| 31k | 405k 50 k 20 k 1M 0.90 100 35
See page 13 for notes.
PerkinElmer Optoelectronics, 10900 Page Ave., St. Louls, MO 63132 USA Phone: 314-423-4900 Fax: 314-423-3956 Web: www.perkinelmer.com/opto
14
Universitat de Vic Control de la temperatura | el llum mitjan ispositi
UVI C Escola Politécnica Р Jançant dispositius sense fils
Superior Ramon Altarriba Roca
SENSOR TEMPERATURA
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ip Texas бэ 9 TMP20
INSTRUMENTS
SBOS466 -DECEMBER 2009
+2.5°С Low-Power, Analog Out
TEMPERATURE SENSOR
Check for Samples: TMP20
FEATURES
12.5°C ACCURACY FROM -55°C to +130°C
SUPPLY VOLTAGE RANGE: 1.8V to 5.5V
LOW POWER: 4HA (max)
MicroSIZE PACKAGES: SOT563, SC70-5
SC70 PIN-COMPATIBLE WITH LM20
APPLICATIONS
CELL PHONES
DESKTOP AND NOTEBOOK COMPUTERS
PORTABLE DEVICES
CONSUMER ELECTRONICS
BATTERY MANAGEMENT
POWER SUPPLIES
HVAC
THERMAL MONITORING
DISK DRIVES
APPLIANCES/WHITE GOODS
AUTOMOTIVE
DRL PACKAGE
SOT563-6
(TOP VIEW)
NC | 1 O 6 | GND
GND | 2 J 5 | №
Your 3 > 4 | V+
Note:
DESCRIPTION
The TMP20 is a CMOS, precision analog output
temperature sensor available in the tiny SOT563
package. The TMP20 operates from —55°C to +130°C
on a supply voltage of 2.7V to 5.5V with a supply
current of 4pA. Operation as low as 1.8V is possible
for temperatures between +15°C and +130°C. The
linear transfer function has a slope of =11.77mv/°C
(typ) and has an output voltage of 1.8639V (typ) at
0°C. The TMP20 has a +2.5%C accuracy across the
entire specified temperature range of -55°C to
+130°C.
The TMP20 4pA (max) supply current limits
self-heating of the device to less than 0.01°C. When
V+ is less than 0.5V, the device is in shutdown mode
and consumes less than 20nA (typ).
The TMP20 is available in either a 5-lead SC70 or
6-lead SOT563 package, reducing the overall board
space required.
DCK PACKAGE
£C70-5
(TOP VIEW)
NC [+] O El GND
емо [2] ©
Y our E œ || V+
NC or no-connect pin must be grounded or left floating. Pin 2 on the DRL package has no intemal connection; pin 2
on the DCK package is connected to the die substrate. See Layout Information for more information about optimizing
the connection of pin 2 on the DCK package for thermal and electrical performance.
A
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
All trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to speciicatons per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of a
| parameters.
Copyright © 2009, Texas Instruments Incorporated
TMP20
SBOS466 -DECEMBER 2009
Ts ors
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This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
Atal ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
PACKAGE INFORMATION"
PRODUCT PACKAGE-LEAD PACKAGE DESIGNATOR PACKAGE MARKING
TMP29 5С70-5 DCK ODB
TMP20 SOT563-6 DRL ODA
(1) For the most current package and ordering information see the Package Option Addendum at the end of this document, or see the Ti
web site at www.ti.com.
ABSOLUTE MAXIMUM RATINGS
Over operating free-air temperature range, unless otherwise noted.
TMP20 UNIT
Supply Voltage, V+ +7.0 \
Operating Temperature Range —55 to +150 °C
Storage Temperature Range _ —65 to +150 °C
Junction Temperature (T, max) +150 °C
Human Body Mode! (HBM) 4000 \
ESD Rating Charged Device Model (CDM) 1000 \
Machine Model (MM) 200 \
(1) Stresses above these ratings may cause permanent damage. Exposure to absolute maximum conditions for extended periods may
degrade device reliability. These are stress ratings only, and functional operation of the device at these or any other conditions beyond
those specified is not implied.
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SBOS486 -DECEMBER 2009
ELECTRICAL CHARACTERISTICS
At T, = +25°C and V+ = 2.7V to 5.5V, unless otherwise noted.
TMP20
PARAMETER CONDITIONS MIN TYP MAX UNIT
TEMPERATURE MEASUREMENT!" |
Accuracy? Ta = -55°C to +130°C —2.5 +2.5 °C
vs Supply V+ = 1.8V to +5.5V, at T, = +15"C to +130°C —0.05 +0.05 ‘CN
V4 = 2.7V 10 +5.5V, at T, = —50°C to +130°C —0.05 +0.05 "CN
Temperature Sensitivity” Ta = —30"C to +100°C =11.4 | —11.77 | -12.2 | т\с
Output Voltage * |
Ta = 0°C 1863.9 | mv
Ta = +25°С 1574 my
Nonlinearity *) 20% < Ta £ +80"C +0.4 %
ANALOG OUTPUT
Output Resistance —GOQUA = | gap € SOOUA 10 O
Load Regulation —GOOUA £ | nap = 600pA 6 my
Maximum Capacitive Load 1 nF
POWER SUPPLY
| Specified Voltage Range Vs TA =-55*C to +130%C 2.7 5.5 \
Ta = +15°С to +130°C® 1.8 5.5 у
Quiescent Current la V+ = 5.5V, Ta = +25% 2.6 4 HA
over Temperature М+ = 5,5\, Т = -55°С to +130°C 6 НА
Shutdown Current len V+ <05V 20 nA
TEMPERATURE RANGE
Specified Operating Range V+=2.7V to 5.5V —55 +130 °С
V+ =1.8V to 5.5V06) +15 +130 °C
Operating Range V+ =2.7V to 5.5V —55 +150 °c
Thermal Resistance Ga
5C70 185 "CAN
SOT563 238 *CAV
Self-Heating
SC70 0.01 °C
SOT563 0.01 °C
(1)
(2)
(3)
(4)
(5)
(6)
100% production tested at T4 = +25°C. Specifications over temperature range are assured by design.
Power-supply rejection is encompassed in the accuracy specification.
Temperature sensitivity is the average slope to the equation Vo = (11.77 x T) + 1.860V.
Your is calculated from temperature with the following equation:
Vo = (-3.88 x 108 x T?) + (-1.15 x 107 x T) + 1.8639V,
where T is in °C.
Nonlinearity is the deviation of the calculated output voltage from the best fit straight line.
The TMP20 transfer function requires the output voltage to rise above the 1.8V supply as the temperature decreases below +15°C.
When operating at a 1.8V supply, it is normal for the TMP20 output to approach 1.8V and remain at that voltage as the temperature
continues to decrease below +15°C. This condition does not damage the device. Once the temperature rises above +15°C, the output
voltage resumes changing as the temperature changes, according to the transfer function specified in this document. For more
information about the transfer function, see the Transfer Function section.
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PIN CONFIGURATIONS
DRL PACKAGE
SOT563-6 Heres
(TOP VIEW) (TOP VIEW)
NG| 1 6 | GND ©
NC [1] 5 | GND
—
Vour | 3 4 | V+ Vou | 3 4 |ve
Note: NC or no-connect pin must be grounded or
left floating.
TMP20 PIN ASSIGNMENTS
TMP20
DRL DCK
PINNAME | PACKAGE | PACKAGE DESCRIPTION
NC 1 1 This pin must be grounded or ieft floating. See Layout information for more information.
NC or GND 2 5 2 This pin must be grounded or left floating. For best thermal response, connect to GND plane.
’ See Layout Information for more information.
Vour 3 3 Analog output.
V+ 4 4 Positive supply voltage.
GND 6 5 Ground pin.
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TMP20
SBOS5466 —DECEMBER 2009
TYPICAL CHARACTERISTICS
OUTPUT IMPEDANCE vs QUIESCENT CURRENT vs
TEMPERATURE TEMPERATURE
6 I
Vg = 5.5V
5
а | 1 /
8 Rout Sinking 5 4
a Ve =2.7V
3 > G 3 ee
E Rout Sinking = TT
5 Vg = 5.5V 8, —
3 | 3
Óó
Rour Source 4
Vg = 5.5V
0 |
-75 —50 -25 © 25 50 75 100 125 150 —5 -50 —25 © 25 50 75 100 125 150
Temperature (*C) Temperature (°C)
Figure 1. Figure 2.
OUTPUT VOLTAGE vs QUIESCENT CURRENT vs
TEMPERATURE SUPPLY VOLTAGE
3.0
V+ =2.7V Тд = +25°С
2.5 =
= DD 3
o “0 TN E
В эх 5
ha =
© 15 ©
5 SN E
ai
3 1.0 8
ë
0.5 >
0 | : >
-75 —50 -25 0 25 50 75 100 125 150 1.5 2.0 25 3.0 3.5 4.0 4.5 5.0 5.5
Temperature (*C) Supply Voltage (V)
Figure 3. Figure 4.
POWER-SUPPLY REJECTION vs POWER-SUPPLY REJECTION vs
TEMPERATURE TEMPERATURE
5 05 5 0.5
Е 20 Typica! Units 5 20 Typical Units
04 ГА! +25°С, +120°С » 4 Гд -50°С
2 0.3 3 0.3
89 02 29 02
5 5 0.1 5 o 0.1
75 8
Bg © 83 ©
- =} e
Э © -0.1 Peon
Е — &
= 02 £5 -02
©. ==” a
a —3 7 —8
S —04 5 04
a —05 e -0.5
15 20 25 30 35 40 45 50 55 15 20 25 30 35 40 45 50 5.5
Supply Voltage (V) Supply Voltage (V)
Figure 5. Figure 6.
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Temperature Error (*C)
Ts ens
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TYPICAL CHARACTERISTICS (continued)
TEMPERATURE ERROR vs
TEMPERATURE
25 - -
39 Typical Units
20 [V4 = 2.7V
1.5
1.0
0.5
-0.5
-1.0
1.5
-20
-2.5
-75 50 -25 0 25 50 75 100 125 150
Temperature (°C)
Figura 7.
WIDEBAND OUTPUT NOISE VOLTAGE
PTT PTT EU LEI I LLL IH ТИТ PTT TT ET TT TEE AM
|, ily: АР di
LL
"PT I Il
aaa EA a Ey E Er Y = À
Ш
I a" I | r В y | |
EE MAY
Output Noise (0.5mV/div)
М+ = 3.3V, T, = +25°C
та yy ya ea u hu |! rd
Time (5ms/div)
Figure 9.
Minimum Veayppır (Y)
MINIMUM SUPPLY VOLTAGE vs TEMPERATURE
3.0
2.5
2.0
1.5
1.0
0.5
0
-75 50 -25 O 25 50 75 100 125 150
Sensor Temperature (*C)
Figure 8.
THERMAL SETTLING
(FLUID-FILLED TEMPERATURE BATH)
V+ =3.3V
T, step from +25°C to +110°C
Vour (200ms/div)
Time (2s/div)
Figure 10.
6
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Superior Ramon Altarriba Roca
REGULADOR DE TENSIO
IB TEXAS
INSTRUMENTS
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LM117, LM317A, LM317-N
SNVS7740 —MAY 2004-REVISED JANUARY 2014
LM117/LM317A/LM317-N Three-Terminal Adjustable Regulator
Check for Samples: LM117, LM317A, LM317-N
FEATURES
+ Specified 1% Output Voltage Tolerance
(LM317A)
Specified max. 0.01%/V Line Regulation
(LM317A)
» Specified max. 0.3% Load Regulation (LM117)
* Specified 1.5A Output Current
« Adjustable Output Down to 1.2V
Current Limit Constant with Temperature
о P"* Product Enhancement tested
« 80 dB Ripple Rejection
e Qutput is Short-Circuit Protected
DESCRIPTION
The LM117 series of adjustable 3-terminal positive
voltage regulators is capable of supplying in excess
of 1.5A aver a 1.2V to 37V output range. They are
exceptionally easy to use and require only two
external resistors to set the output voltage. Further,
both line and load regulation are better than standard
fixed regulators. Also, the LM117 is packaged in
standard transistor packages which are easily
mounted and handled.
In addition to higher performance than fixed
regulators, the LM117 series offers full overload
protection available only in IC's. Included on the chip
are current limit, thermal overload protection and safe
area protection. All overioad protection circuitry
remains fully functional even if the adjustment
terminal is disconnected.
Normally, no capacitors are needed unless the device
is situated more than 6 inches from the input filter
capacitors in which case an input bypass is needed.
An optional output capacitor can be added to improve
transient response. The adjustment terminal can be
bypassed to achieve very high ripple rejection ratios
which are difficult to achieve with standard 3-terminal
regulators.
Besides replacing fixed regulators, the LM117 is
useful in a wide variety of other applications. Since
the regulator is “floating” and sees only the input-to-
output differential voltage, supplies of several
hundred volts can be regulated as long as the
maximum input to output differential is not exceeded,
1.e., avoid short-circuiting the output.
Also, it makes an especially simple adjustable
switching regulator, a programmable output regulator,
or by connecting a fixed resistor between the
adjustment pin and output, the LM117 can be used
as a precision current regulator. Supplies with
electronic shutdown can be achieved by clamping the
adjustment terminal to ground which programs the
output to 1.2V where most loads draw little current.
For applications requiring greater output current, see
LM150 series (3A) and LM138 series (5A) data
sheets. For the negative complement, see LM137
series data sheet.
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
All trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does nat
necessarily include testing of all parameters.
Copyright © 2004-2014, Texas Instruments Incorporated
SNVS7740 —MAY 2004 -REVISED JANUARY 2014 www.ti.com
Typical Applications
LM117
Vin 2: 28V Vin any? UT @—vour!!
< ni
< 240
cre ot
DAF 1uf
a
/è Ek
Full output current not available at high input-output voltages
*Needed if device is more than 6 inches from filter capacitors.
Optional —improves transient response. Output capacitors in the range of 1 pF to 1000 pF of aluminum or tantalum
electrolytic are commonly used to provide improved output impedance and rejection of transients.
ttVouT = 1.25V ( + =) + lapy(Rz)
Figure 1. 1.2V-25V Adjustable Regulator
LM117/LM317A/LM317-N Package Options
Part Number Package Drawing Package Type Output Current
LM117K STEEL
NDS TO-3
LM317K
LM317AT
NDE 1.5A
LM317T TO-220
LM317T/LFO1 NDG
LM31765 KTT TO-263
LM317AEMP
DCY SOT-223 1.0A
LM317EMP
LM117H
LM317AH NDT TO
LM317H 0.5A
LM317AMDT
NDP TO-252
LM317MDT
NOTE
For part numbers that can be ordered, please see the Package Option Addendum at the
end of the datasheet.
SOT-223 vs. TO-252 Packages
bon A=
SOT-223 PFM
Figure 2. Scale 1:1
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Connection Diagrams
ADJUSTMENT Vin
CASE IS OUTPUT
Figure 3. TO-3 (NDS)
Metal Can Package
Bottom View
Package Drawing NDS
INPUT
TAB IS
OUTPUT OUTPUT
ADJ
Figure 5. TO-263 (KTT)
Surface-Mount Package
Top View
Package Drawing KTT
ADJ
Your Vout
YIN
Figure 7. 4-Lead SOT-223 (DCY)
Top View Surface-Mount Package
Package Number DCY
LM117, LM317A, LM317-N
SNVS7740 —MAY 2004—REVISED JANUARY 2014
INPUT
O--——— ADJUSTMENT
OUTPUT
CASE IS OUTPUT
Figure &. TO (NDT)
Metal Can Package
Bottom View
Package Drawing NDT
АО — — = Vin
uJ | ыы
Убит
Figure 6. TO-220 (NDE}
Plastic Package
Front View
Package Drawing NDE
| | Input
feb is — Output
OUT
| | Adj/GND
Figure 8. TO-252 (NDP)
Front View Surface Mount Package
Package Drawing NDP
A These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
A ad during storage or handling to prevent electrostatic damage to the MOS gates.
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ABSOLUTE MAXIMUM RATINGS 102)
Power Dissipation internally Limited
Input-Output Voltage Differential +40V, -0.3V
Storage Temperature 65°C to +150°C
Lead Temperature Metal Package (Soldering, 10 seconds) 300°C
Plastic Package (Soldering, 4 seconds) 260°C
ESD Tolerance © 3 kv
(1) Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for
which the device is intended to be functional, but do not ensure specific performance limits. For ensured specifications and test
conditions, see the Electrical Characteristics. The ensured specifications apply only for the test conditions listed.
(2) If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/Distributors for availability and
specifications.
(3) Human body model, 100 pF discharged through a 1.5 kQ resistor.
OPERATING TEMPERATURE RANGE
LM117 =55°С = T, = +150°C
LM317A —40°C < T, = +125°C
LM317-N 0°С < T,s+125°C
Preconditioning
Thermal Limit Bum-In All Devices 100%
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SNVS7740 —-MAY 2004-REVISED JANUARY 2014
LM317A and LM317-N ELECTRICAL CHARACTERISTICS!
Specifications with standard type face are for T, = 25°C, and those with boldface type apply over full Operating
Temperature Range. Unless otherwise specified, Viy = Vour = 5V, and lour = 10 mA.
Wes rs
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LM317A LM317-N
Parameter Conditions Unit
Min Typ Max Min Typ | Max в
1.238 | 1.250 | 1.262 - 1.25 - \
Reference Voltage 3V = (Vin — Vour) $ 40V,
10 mA < lour < мах 1.225 | 1.250 | 1.270 | 1.20 | 1.25 | 1.30 | V
_ (2) 0.005 | 0.01 0.01 | 0.04
Line Regulation 3V < (Vin 7 Vour) € 40V 0.01 0.02 0.02 | 0.07 VV
1 (1} (2) 0.1 0.5 0.1 0.5
Load Regulation 10 mA < lour € Imax 0.3 1 0.3 15 %
Thermal Regulation 20 ms Pulse 0.04 0.07 0.04 | 0.07 | %/W
Adjustment Pin Current 50 100 50 100 | pA
Adjustment Pin Current 10 mA $ loyr $ Imax'?
Change 3V < (Vin = Vour) $ 40V pa 5 02 | 5 | А
Temperature Stability Twin $ Ty $ TMax 1 1 %
Minimum Load Current (Vin - Your) = 40V 3.5 10 3.5 | 10 | mA
NDS, KTT Packages - - - 1.5 2.2 34
(Vin = VouT) € 15V DCY, NDE Packages 1.5 2.2 3.4 1.5 2.2 3.4 A
o NDT Package 0.5 0.8 1.8 0.5 0.8 1.8
Current Limit
NDS, KTT Packages - - 0.15 | 0.40
(Vin = Vout) = 40V DCY, NDE Packages 0.15 0.40 0.15 | 0.40 A
NDT Package 0.075 | 0.20 0.075 | 0.20
RMS Output Noise, % of | 40 Hz < fs 10 kkz 0.003 0.003 %
Our
Vour = 10V, f= 120 Hz, Cap; = 0 WF 65 B
Ripple Rejection Ratio our ADJ E 65 I
Voyr = 10V, f= 120 Hz, Cap, = 10 pF 66 80 66 80 dB
Long-Term Stability T,= 125°C, 1000 hrs 0.3 1 0.3 1 %
NDS (TO-3) Package - 2
NDE {T0O-220) Package 4 4
Thermal Resistance, 8,c KTT (TO-263) Package - 4 SCAN
Junction-to-Case DCY (SOT-223) Package 23.5 23.5
NDT (TO) Package 21 21
NDP (TO-252) Package 12 12
NDS (TO-3) Package - 39
NDE (TO-220) Package 50 50
Thermal Resistance, 6,4 (3)
Junction-to-Ambient KIT (10-263) Package В 20 "CW
(No Heat Sink) DCY (SOT-223) Package ® 140 140
NDT (TO) Package 186 186
NDP (TO-252) Package 103 103
(1) Imax = 1.5A for the NDS (TO-3), NDE (TO-220), and KTT (TO-263) packages. Imax = 1.0A for the DCY (SOT-223) package. Imax = 0.5A
for the NDT (TO) and NDP (TO-252) packages. Device power dissipation {Pp} is limited by ambient temperature (T,), device maximum
junction temperature (T,}, and package thermal resistance (0,4). The maximum allowable power dissipation at any temperature is :
Ppmax) = Tama: - TA)/O ja). All Min. and Max. limits are ensured to TI's Average Outgoing Quality Level (AOQL).
(2) Regulation is measured at a constant junction temperature, using pulse testing with a low duty cycle. Changes in output voltage due to
heating effects are covered under the specifications for thermal regulation.
(3) When surface mount packages are used (TO-263, SOT-223, TO-252), the junction to ambient thermal resistance can be reduced by
increasing the PC board copper area that is thermally connected to the package. See the APPLICATION HINTS section for heatsink
techniques.
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LM117 ELECTRICAL CHARACTERISTICS
Specifications with standard type face are for T; = 25°C, and those with boldface type apply over full Operating
Temperature Range. Unless otherwise specified, Vin = Vout = 8V, and loyr = 10 mA.
LM117, LM317A, LM317-N
5NVS7740 —MAY 2004—REVISED JANUARY 2014
LM117 (2)
Parameter Conditions
Min Typ Max Units
ЗУ <= (Vin = Vout) £40V,
Reference Voltage 10 mA $ lour $ Imax 1.20 1.25 1.30 \
; . 0.01 .
Line Regulation 3V 5 (Vin - Vour) € 40V 0.02 de %N
i (1) (3) 0.1 0.3 o
Load Regulation 10 mA $ loyr £ Imax 03 q Yo
Thermal Regulation 20 ms Pulse 0.03 0.07 MAN
Adjustment Pin Current 50 100 НА
10 MA = юрт $ max”?
Adjustment Pin Current Change ЗУ £ (Vin - Vour) $ 40V 0.2 5 HA
Temperature Stability TMIN $ Ty £ TMAx 1 %
Minimum Load Current Vin — Vout) = 40V 3.5 5 mA
Vix = Vour) $ 15V NDS Package 1.5 2.2 34 A
uu мол МОТ Раскаде 0.5 08 | 1.8
Current Limit
(Vin = Vour) = 40V NDS Package 0.3 0.4 A
MM NDT Package 0.15 | 020
RMS Output Noise, % of Vour | 10 Hz <f< 10 kHz 0.003 %
Vour = 10V, f= 120 Hz, Caps = 0 uF 65 dB
Ripple Rejection Ratio our ADJ E
Vout = 10V, f= 120 Hz, Cap, = 10 pF 66 80 dB
Long-Term Stability T, = 125°C, 1000 hrs 0.3 1 %
Thermal Resistance, 0,c NDS (TO-3) Package 2 °
; CAN
Junction-to-Case NDT (TO) Package 21
Thermal Resistance, 8, NDS (TO-3) Package 39
Junction-to-Ambient ‘CAN
(No Heat Sink) NDT (TO) Package 186
(1)
Мах = 1.БА for the NDS (TO-3), NDE (TO-220), and KTT (TO-263) packages. Imax = 1.0A for the DCY (SOT-223) package. Imax = 0.5A
for the NDT (TO) and NDP (TO-252) packages. Device power dissipation {Pp) is limited by ambient temperature (Ts), device maximum
junction temperature {T,), and package thermal resistance (0,4). The maximum allowable power dissipation at any temperature is :
Pomaxy = ((Tamaxy - Ta¥8,4). All Min. and Max. limits are ensured to TI's Average Outgoing Quality Level (AOQL).
(2)
(3)
heating effects are covered under the specifications for thermal regulation.
Specifications and availability for military and space grades of LM117/883 can be found in the LM117QML datasheet (SNVS356).
Specifications and availability for military and space grades of LM117/JAN can be found in the LM117JAN datasheet (SNVS365).
Regulation is measured at a constant junction temperature, using pulse testing with a low duty cycle. Changes in output voltage due to
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OUTPUT VOLTAGE DEVIATION (%)
ADJUSTMENT CURRENT (uA)
Vour (Y)
LM117, LM317A, LM317-N
TYPICAL PERFORMANCE CHARACTERISTICS
Output Capacitor = 0 pF unless otherwise noted
Load Regulation
0 ‘ит =
lour = 1.54
Vin = 15V
Voyur = 10V
—0.8
-1.0
~75 —50 -25 0 25 50 75 100 125 150
TEMPERATURE (°С)
Figure 9.
Adjustment Current
60
arr
55
50 7
45
40
35
—75 -50 -25 0 725 50 75 100 125 150
TEMPERATURE (*C)
Figure 11.
Vout V8 Vins Vout = VRer
1.4 Vout = 1.25V
T,= 25°C
1.2
1.0 = R1+R2
0.8
0.6
0.4
0.2
0.0
Vin (Y)
Figure 13.
INPUT-OUTPUT DIFFERENTIAL (V) OUTPUT CURRENT (A)
Your (V}
Current Limit
— KTT, NDE, NDS
2 = = PACKAGE DEVICES |
Ÿ
Т = 150°C
z
7
j 1 1 1
NDT PACKAGE DEVICES
0 10 x 30 40
INPUT-OUTPUT DIFFERENTIAL (V)
Figure 10.
Dropout Voltage
+
1
AVGUT = 100 ту
25
I
№
2.0 ~~
T=
—
aur = 1.54 a
lour = 1A
|
Ny: nur = 500 mA
el DUT =
Че
louT = 200 mA “|
| | lour = 20 mA
1.0 3 и 3 |
-75 —50 —25 0 25 50 75 100 125 150
TEMPERATURE {°C)
Figure 12.
15 rd
Your Ys Vin: Vour = BV
0
Vour = 5V
T, = 25°C
R1 = 2430
0 1 2 3 4 5 86 7 8 9 10
Ум (М)
Figure 14.
SNVS7740 -MAY 2004 -REVISED JANUARY 2014
Copyright © 2004-2014, Texas Instruments Incorporated
Product Folder Links: LM117 LM317A LM317-N
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Y TES ETS
www.tl.com
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
Qutput Capacitor = 0 pF unless otherwise noted
Temperature Stability
Minimum Operating Current
1.260 4.5
_ 4.0
= —
w 1.250 << E 35
eS o
= и” N = 3.0
= =
> N me 25
ow 1.240 =
= N =
= N -- 2.0
[TT] =
ec a 15
a 1.230 i
er = 1.0
=
0.5
1.220 0
—75 —50 -25 D 25 50 75 106 125 150 и 10 20 30 an
TEMPERATURE (°C) INPUT-OUTPUT DIFFERENTIAL {V}
Figure 15. Figure 186.
Ripple Rejection Ripple Rejection
100 — 100 -
Capy = QuE lout = 500
- 80 ~ B80 Vout = 10V
m “| | = OUT
= NN Capy=-0 = 1; = 25°C
= Ва = Сао, =
= 60 = 160
Е 5
= a
hid | ыы
Ш 40 = 40
É pue E
= | ‘OUT > > =
20 —(= 120 Hz 20
Tj= 25°C
| ] | 0
0 5 10 15 20 25 30 3% 10 100 1 10k 100k IM
OUTPUT VOLTAGE (V) FREQUENCY (Hz)
Figure 17. Figure 18.
Ripple Rejection Cutput Impedance
100 10
Vin = 15V
À Vour = 10V
— 30 В lour = 500 mA
= нана раодиорити С = 10uF out
SAL Nes 2 Briar
Q 60 jr ОАО =
5 Садо) = - 4
= © 107
E 4 =
= Vin = 15V 5
= \ = 10\ —2
OUT E: 10
“ 20 1-120 m4 >
Ti = 25°C
0 LAA 1073
0.01 0.1 1 10 19 190 Tk 10k 100k 1M
OUTPUT CURRENT (A) FREQUENCY (Hz)
Figure 19. Figure 20.
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www.ti.com SNVS7740 —MAY 2004—REVISED JANUARY 2014
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
Output Capacitor = 0 uF unless otherwise noted
Line Transient Response Load Translent Response
15 3
о 2
w 10 = uF; = 1QuF <= >
<> >= 1
ES 05 - az
= = = CADJ =D > - 0
> = 0 5 = 4 C= uF; Cppy=10uF
= > _05 YouT=10V 3 Vin = 15V
> E 18 lay; = 50 mA = -2 Your = 10\
* Tj=25 С = —3 Iyı = 50 mA
-15 = 15 Tj = 25°C
w > 11 u 10
БЕ EC
a5 05 = 05
= od
ax 5
> 0 xr 0
0 10 20 30 40 = 0 10 20 30 40
TIME (us) TIME (us)
Figure 21. Figure 22.
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LM117, LM317A, LM317-N Texas
SNVS57740 — MAY 2004—REVISED JANUARY 2014 www.ti.com
APPLICATION HINTS
In operation, the LM117 develops a nominal 1.25V reference voltage, Vrer, between the output and adjustment
terminal. The reference voltage is impressed across program resistor R1 and, since the voltage is constant, a
constant current |, then flows through the output set resistor R2, giving an output voltage of
R2
Vout = YrEF (1 + 55) + lap4FR2
(1)
Since the 100 pA current from the adjustment terminal represents an error term, the LM117 was designed to
minimize lan, and make it very constant with line and load changes. To do this, all quiescent operating current is
returned to the output establishing a minimum load current requirement. If there is insufficient load on the output,
the output will rise.
External Capacitors
An input bypass capacitor is recommended. A 0.1 pF disc or 1uF solid tantalum on the input is suitable input
bypassing for almost all applications. The device is more sensitive to the absence of input bypassing when
adjustment or output capacitors are used but the above values will eliminate the possibility of problems.
The adjustment terminal can be bypassed to ground on the LM117 to improve ripple rejection. This bypass
capacitor prevents ripple from being amplified as the output voltage is increased. With a 10 uF bypass capacitor
80 dB ripple rejection is obtainable at any output level. Increases over 10 pF do not appreciably improve the
ripple rejection at frequencies above 120 Hz. If the bypass capacitor is used, it is sometimes necessary to
include protection dicdes to prevent the capacitor from discharging through internal low current paths and
damaging the device.
In general, the best type of capacitors to use is solid tantalum. Solid tantalum capacitors have low impedance
even at high frequencies. Depending upon capacitor construction, it takes about 25 uF in aluminum electrolytic to
equal 1uF solid tantalum at high frequencies. Ceramic capacitors are also good at high frequencies; but some
types have a large decrease in capacitance at frequencies around 0.5 MHz. For this reason, 0.01 YF disc may
seem to work better than a 0.1 uF disc as a bypass.
Although the LM117 is stable with no output capacitors, like any feedback circuit, certain values of external
capacitance can cause excessive ringing. This occurs with values between 500 pF and 5000 pF. A 1 pF solid
tantalum (or 25 YF aluminum electrolytic) on the output swamps this effect and insures stability. Any increase of
the load capacitance larger than 10 pF will merely improve the loop stability and output impedance.
Load Regulation
The LM117 is capable of providing extremely good load regulation but a few precautions are needed to obtain
maximum performance. The current set resistor connected between the adjustment terminal and the output
terminal (usually 2400) should be tied directly to the output (case) of the regulator rather than near the load. This
eliminates line drops from appearing effectively in series with the reference and degrading regulation. For
example, a 15V regulator with 0.05 resistance between the regulator and load will have a load regulation due to
line resistance of 0.050 х ||. № №е set resistor is connected near the load the effective line resistance will be
0.050 (1 + R2/R1) or in this case, 11.5 times worse.
Figure 23 shows the effect of resistance between the regulator and 240Q set resistor.
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Figure 23. Regulator with Line Resistance in Output Lead
With the TO-3 package, it is easy to minimize the resistance from the case to the set resistor, by using two
separate leads to the case. However, with the TO-39 package, care should be taken to minimize the wire length
of the output lead. The ground of R2 can be returned near the ground of the load to provide remote ground
sensing and improve load regulation.
Protection Diodes
When external capacitors are used with any IC regulator it is sometimes necessary to add protection diodes to
prevent the capacitors from discharging through low current points into the regulator. Most 10 uF capacitors have
low enough internal series resistance to deliver 20A spikes when shorted. Although the surge is short, there is
enough energy to damage parts of the IC.
When an output capacitor is connected to a regulator and the input is shorted, the output capacitor will discharge
into the output of the regulator. The discharge current depends on the value of the capacitor, the output voltage
of the regulator, and the rate of decrease of Vin. In the LM117, this discharge path is through a large junction that
is able to sustain 15A surge with no problem. This is not true of other types of positive regulators. For output
capacitors of 25 uF or less, there is no need to use diodes.
The bypass capacitor on the adjustment terminal can discharge through a low current junction. Discharge occurs
when either the input, or the output, is shorted. Internal to the LM117 is a 50Q resistor which limits the peak
discharge current. No protection is needed for output voltages of 25V or less and 10 JF capacitance. Figure 24
shows an LM117 with protection diodes included for use with outputs greater than 25V and high values of output
capacitance.
Vout = 1.25\ (- + EF) + lapyR2
Di protects against C1
D2 protects against C2
Figure 24. Regulator with Protection Diodes
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Heatsink Requirements
The LM317-N regulators have internal thermal shutdown to protect the device from over-heating. Under all
operating conditions, the junction temperature of the LM317-N should not exceed the rated maximum junction
temperature (T,) of 150°C for the LM117, or 125°C for the LM317A and LM317-N. A heatsink may be required
depending on the maximum device power dissipation and the maximum ambient temperature of the application.
To determine if a heatsink is needed, the power dissipated by the regulator, P5, must be calculated:
Pp = (Vin — Your) * 11) + (Vin x Ig) (2)
Figure 25 shows the voltage and currents which are present in the circuit.
The next parameter which must be calculated is the maximum allowable temperature rise, Tr¿ax:
Trmaxy = Tumaxy 7 Tamao (3)
where Tumax is the maximum allowable junction temperature (150%C for the LM117, or 125°C for the
LM317A/LM317-N), and Tamax is the maximum ambient temperature which will be encountered in the
application.
Using the calculated values for Trax; &nd Pp, the maximum allowable value for the junction-to-ambient thermal
resistance (0,4) can be calculated:
бд = (Trax) / Po) (4)
Ш
[Led Те
Figure 25. Power Dissipation Diagram
If the calculated maximum allowable thermal resistance is higher than the actual package rating, then no
additional work is needed. If the calculated maximum allowable thermal resistance is lower than the actual
package rating either the power dissipation (Pp) needs to be reduced, the maximum ambient temperature Tamax
needs to be reduced, the thermal resistance (6,4) must be lowered by adding a heatsink, or some combination of
these.
If a heatsink is needed, the value can be calculated from the formula:
Bua S (Ba - (Ben + Oc) (5)
where (Ocy is the thermal resistance of the contact area between the device case and the heatsink surface, and
8,c is thermal resistance from the junction of the die to surface of the package case.
When a value for 8,,_,, is found using the equation shown, a heatsink must be selected that has a value that is
less than, or equal to, this number.
The 8-4) rating is specified numerically by the heatsink manufacturer in the catalog, or shown in a curve that
plots temperature rise vs power dissipation for the heatsink.
Heatsinking Surface Mount Packages
The TO-263 (KTT), SOT-223 (DCY) and TO-252 (NDP) packages use a copper plane on the PCB and the PCB
itself as a heatsink. To optimize the heat sinking ability of the plane and PCB, solder the tab of the package to
the plane.
Heatsinking the SOT-223 (DCY) Package
Figure 26 and Figure 27 show the information for the SOT-223 package. Figure 27 assumes a 9% -A) Of 74°C/W
for 1 ounce copper and 51°C/W for 2 ounce copper and a maximum junction temperature of 125°C. Please see
AN-1028 (literature number SNVA036) for thermal enhancement techniques to be used with SOT-223 and TO-
252 packages.
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140 —
110 +
80 —
THERMAL RESISTANCE 6(J-A} IN °C/W
200 —
170 +
LM117, LM317A, LM317-N
SNVS7740 —MAY 2004 -REVISED JANUARY 2014
50
1 2
COPPER FCIL AREA (SQ. IN.)
Figure 26. 0,_,, vs Copper (2 ounce) Area for the SOT-223 Package
MAX POWER DISSIPATION (W)
1 OUNCE COPPER
507-223 PACKAGE
PCB MOUNT
1 50. IN. COPPER
2 OUNCE COPPER
и
25
75
AMBIENT TEMPERATURE (°C)
Figure 27. Maximum Power Dissipation vs Tug for the SOT-223 Package
Heatsinking the TO-263 (KTT) Package
Figure 28 shows for the TO-263 the measured values of 8,-,, for different copper area sizes using a typical PCB
with 1 ounce copper and no solder mask over
As shown in Figure 28, increasing the coppe
the copper area used for heatsinking.
r area beyond 1 square inch produces very little improvement. №
should also be observed that the minimum value of §,_,) for the TO-263 package mounted to a PCB is 32°C/W.
80 -
70 —
60 —
50 -
40 —
THERMAL RESISTANCE 6(J-A) IN °C/W
30
a
COPPER FOIL AREA (SQ. IN.)
Figure 28. 8, , vs Copper (1 ounce) Area for the TO-263 Package
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As a design aid, Figure 29 shows the maximum allowable power dissipation compared to ambient temperature
for the TO-263 device (assuming 0-5, is 35°C/W and the maximum junction temperature is 125°C).
5 —
E 4
=
<
г
a 5 -
Ln
in
0
но 2 -
=
© TO-263 PACKAGE
> PCB MOUNT
1 —
= 1 SQ. iN. COPPER
0 j | y
-40 -25 25 75 125
AMSIENT TEMPERATURE (°C)
Figure 29. Maximum Power Dissipation vs Tayg for the TO-263 Package
Heatsinking the TO-252 (NDP) Package
If the maximum allowable value for 8,, is found to be 2103°C/W (Typical Rated Value) for the TO-252 package,
no heatsink is needed since the package alone will dissipate enough heat to satisfy these requirements. If the
calculated value for 8, falls below these limits, a heatsink is required.
As a design aid, Table 1 shows the value of the 8, of NDP the package for different heatsink area. The copper
patterns that we used to measure these 6,,S are shown in Figure 34. Figure 30 reflects the same test results as
what are in Table 1.
Figure 31 shows the maximum allowable power dissipation vs. ambient temperature for the TO-252 device.
Figure 32 shows the maximum allowable power dissipation vs. copper area (in“) for the TO-252 device. Please
see AN-1028 (literature number SNVA036) for thermal enhancement techniques to be used with SOT-223 and
TO-252 packages.
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LM117, LM317A, LM317-N
SNVS7740 — MAY 2004 -REVISED JANUARY 2014
Table 1. 9,, Different Heatsink Area
Layout Copper Area Thermal Resistance
Top Side (in?) Bottom Side (in?) (84°C) TO-252
1 0.0123 0 103
2 0.066 0 87
3 0.3 0 60
4 0.53 0 54
5 0.76 0 52
6 1.0 0 47
7 0.066 0.2 84
8 0.066 0.4 70
g 0.066 0.6 63
10 0.066 0.8 57
11 0.066 1.0 57
12 0.066 0.066 89
13 0.175 0.175 72
14 0.284 0.284 61
15 0.392 0.392 55
16 0.5 0.5 53
(1) Tab of device attached to topside of copper.
120 T
TA = 25%
Still Air
100 H
AS
LAN
/
В
Thermal Resistance (8,,°C/W)
Top Cu
40 1/2 Top +
1/2 Bottom
20
0
0 0.2 0.4 0.6 0.8 1.0
2 ог Copper Area (in), T0252
Figure 30. 0,, vs 20z Copper Area for TO-252
Still Air
207 Cu on
Top Plane
Ba =!
Maximum Allowable Power Dissipation (W)
G 25 50 75 100 125
Ambient Temperature (°C), T0252
Figure 31. Maximum Allowable Power Dissipation vs. Ambient Temperature for TO-252
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4
T, = 25°C 1/2 Top +
Still Air 1/2 Bottom
Maximum Allowable Power Dissipation (W)
0 0.2 0.4 0.6 0.8 1
2 oz Copper Area (in), T0252
INSTRUMENTS
www.tl.com
Figure 32. Maximum Allowable Power Dissipation vs. 20z Copper Area for TO-252
; в
16
E == In LE E E = =
—
=
Figure 33. Top View of the Thermal Test Pattern in Actual Scale
16
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Figure 34. Bottom View of the Thermal Test Pattern in Actual Scale
Schematic Diagram
LM117, LM317A, LM317-N
SNVS7740 —MAY 2004 —REVISED JANUARY 2014
E
il.
+
RI
2
e E +
RUS
111 >
ns > A13
100 4 p 5.11 APN
R2§
R26 4
Lt < 3
= — Yaur
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UV! C AR Control de la temperatura ¡ el llum mitjangant dispositius sense fils
Superior Ramon Altarriba Roca
OPTOACOBLADOR
TOSHIBA 6N138 6N139
TOSHIBA Photocoupler GaAfAs Ired & Photo IC
6N138, 6N139
Current Loop Driver. Unit in mm
Low Input Current Line Receiver.
CMOS Logic Interface. 8758
q
The TOSHIBA 6N138 and 6N139 consists of a GaAlAs + |
infrared 753% |
emitting diode coupled with a split-Darlington output 20
configuration, 0.06202 e TEE 0.05.
À high speed GaAfAs Ired manufactured with an unique a
LPE junction, has the virtue of fast rise and fall time at ПП ПТ | |8
] ) , 1.2 + 0.15 o
ow drive current oo 12 | 0250
e Isolation voltage: 2500Vrms (min.) oi Thos a 7.85~8.80
e Current transfer ratio
: EN138 — 300% (min) (F=1.6mA)
: EN 139 — 400% (min.) (IF=0.5mA) 1.1004
e Switching time: 6N138 — tPHL=10us (max.)
— tPLH=35ps (max.)
6N139 — tPHL=1ys (max.) TOSHIBA 11-10C4
— tPLH=7ps (max.) Weight: 0.54 g
o UL recognized: UL1577, file no. E67349
Pin Configuration (top view)
1:N.C.
; | Z : Anode
3 Cathode
E 7 | 4 N.C.
A 5 Gnd
B e] 6 : Output
7 - Output Base
m 8: \Усс
5 |
E 5
Schematic
Усс
1 2002-09-25
TOSHIBA
6N138,6N139
Maximum Ratings (*) (Ta = 0°C to + 70°C)
Characteristic Symbol Rating Unit
Forward current (Note 1) IF 20 mA
Pulse forward current Ep 40 mA
В Total pulse forward current Ip"? 1 A
Reverse voltage VR 5 \
Diode power dissipation (Note 2) Pp 35 mw
Output current (Note 3) lo 60 mA
5 Emitter-base reverse voltage VER 0.5 \
® Supply voltage Vec” —0.5 to 18 \
D
© | Output voltage Vol —0.5 to 18 у
Output power dissipation {Note 4) Po 100 mw
Operating temperature range Topr 0 to 70 °С
Storage temperature range Tstg —55 to 125 °C
Lead solder temperature (10s) ©* Tsol 260 °C
2500 \
Isolation voltage (1min., R.H.s 60%) BV din
(*) JEDEC registered data
(**) Not registered JEDEC
(*1) 50% duty cycle, 1ms pulse width
(*2) Pulse width 1us, 300pps
(*3) 6N138--- —0.5 to 7V
(*4) 1.6mm below seating plane
2 2002-09-25
TOSHIBA 6N138,6N139
Electricai Characteristics
Over Recommended Temperature (Ta = 0°C to 70°C, unless otherwise noted)
Characteristic Symbol Test Condition Min. | C5)Typ. | Max. Unit
IF=0.5MA, Vo=0.4V
Current transfer CTR() %
ratio (Note 5, 6) I-=1.6MA, Vo=0.4V 500 900 —
6N138 Vec=4.5v 300 | 600 | —
IF=1.6mA, lo=6.4mA
Vec=4.5V — 0.1 0.4
IF=5MÁ, lo=15mA
EN 139 _ — 0.1 0.4
Logic low output Vo Vec=4.5V V
voltage (Note 6) L \e=12MA, lo=24MA
Vec=4.5V — | 82 | 04
6N138 RO — | 01 | 04
Logic high output 6N139 lo") IF=0MA, Vo=Ycc=18V — 0.05 100 LA
current (Note 6) | 6N138 IF=0MA, Vo=Vcc=7V — | 0.05 | 250
Logic low supply current IF=1.6mA, Vo=0pen
(Note 6) | 'CCL |Vec=5V — | 92 | — mA
Logic high su current
gic high supply Notes) | сен | IF=0mA, Vo=Open, Vec=5V — 10 | — nA
Input forward voltage VE(™) IF=1.6mA, Ta=25°C — 1.65 1.7 \
Input reverse breakdown * _ —75o
voltage BVYRr(”) {Ir=10pA, Ta=25°C 5 — — Y
Temperature coefficient of _ В
forward voltage AVE / ATa | IE=1.8mMA — -1.9 — mV /°C
Input capacitance CIN f=1MHz, Vr=0 — 60 — pF
Resistance (input-output) Ro E (Note 7), | __ 10" — Q
Capacitance (input-output) Cro f=1MHz (Note 7) — 0.6 — pF
(**) JEDEC registered data.
(*5) All typicals at Ta=25°C and Vcc=5V, unless otherwise noted.
3 2002-09-25
TOSHIBA 6N138,6N139
Switching Specifications (Ta=25"C, Vec=5V, unless otherwise specified)
ва Тез! а
Characteristic Symbol Circuit Test Condition Min. | Typ. | Max. Unit
IF=0.5mMA, R_=4.7k0 — 5 25
Propagation delay 8N 139 a T
time to logic low toHL(") 1 IF=12mA, R_=2700 — 0.2 1 us
at output (Note 6, 8)
EN 138 IF=1.686mA, R_=2.2k0 — 1 10
. IF=0.5MA, R_=4.7kQ — 5 60
Propagation delay 6N 139
time to logic high toLH(*) 1 \e=12mA, R,=2700 — 1 7 us
at output (Note 6, 8)
BN138 ir=1.6mA, R =2.2kQ — 4 35
Common mode transient _ _
immunity at logic high CMy э | | Оль И 2 2КО — | 500 | — | v/ıs
level output (Note 9) CM PP
Common mode transient Ir=1.6MA
inmunity at logic low CML 2 R =2.2k0 — 150 | — Y 1 us
level output (Note 9) Усм=400\ р-р
(*YJEDEC registered data.
(Note 1):
(Note 2):
(Note 3):
(Note 4):
Derate linearly above 50°C free-air temperature at a rate of 0.4mA / *C
Derate linearly above 50°C free-air temperature at a rate of 0.7mW / °C
Derate linearly above 25°C free-air temperature at a rate of 0.7mA / *C
Derate linearly above 25°C free-air temperature at a rate of 2.0mW / °C
(Note 5):
(Note 6):
(Note 7):
(Note 8):
(Note 9):
DC CURRENT TRANSFER RATIO is defined as the ratio of output collector current, lo, to the forward
LED input current, IF, times 100%.
Pin 7 open.
Device considered a two-teminal device: Pins 1, 2, 3, and 4 shorted together and Pins 5, 6, 7 and 8
shorted together.
Use of a resistor between pin § and 7 will decrease gain and delay time.
Common mode transient immunity in logic high level is the maximum tolerable (positive) dvcMm / dt on
the leading edge of the common mode pulse, VcM, to assure that the output will remain in a logic high
state (Le., YO > 2.0V).
Common mode transient immunity in Logic Low level is the maximum tolerable (negative) dvcm / dt on
the trailing edge of the common mode pulse signal, Vom, to assure that the output will remain in a logic
low state (i.e., Vo < 0.8V).
2002-09-25
TOSHIBA
6N138,6N139
Test Circuit 1.
IF
Pulse gen.
o— | Zo=509 Ir [A] e]
tr= 5ns +5V
10% Duty cycle
(Saturated e) 1.5V 11.5V 1/f< 100us 6 Vo
Vi
О IF Monitor [4 5] CL ©)
tpHL tpLH с | ]
— > = T o
=
Yo — 110% 90% 5V
(Non-
Saturated 0% 10%
Response) —»e!
(*)CL is approximately 15pF which includes probe
and stray wiring capacitance.
Test Circuit 2.
Rec
ts tr= 0.64 8 0 +5V
400\ — — ESTE 1
90% 7] $ J
Vem 10% -
— ov 6 O Vo
tr f
nun —
5
Vo 5” sv
Swith at A: IF = OmA +
vo + @—
Vo И
Swith at B : Ir = 1.6mA Pulse gen
2002-09-25
TOSHIBA 6N138,6N139
RESTRICTIONS ON PRODUCT USE 000707EBC
e 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..
e 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.
e Gallium arsenide (GaAs) is a substance used in the products described in this document. GaAs dust and fumes
are toxic. Do not break, cut or pulverize the product, or use chemicals to dissclve them. When disposing of the
products, follow the appropriate regulations. Do not dispose of the products with other industrial waste or with
domestic garbage.
e The products described in this document are subject to the foreign exchange and foreign trade laws.
e 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.
6 2002-09-25
Universitat de Vic , age . re
UV! C Escola Politécnica Control de la temperatura ¡ el llum mitjancant dispositius sense fils
Superior Ramon Altarriba Roca
AMPLIFICADOR OPERACIONAL
TLV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/QUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
Micro-Power Operation... < 1 uÂ/Channel
input Common-Mode Range Exceeds the
Rails ... —0.1 Y to Vcc +5V
Reverse Battery Protection Up To 18 У
Rail-to-Rail Input/Output
Gain Bandwidth Product... 5.5 kHz
Supply Voltage Range .. . 2.5 V to 16 V
Specified Temperature Range
— Тд = 0°С to 70°C... Commercial Grade
— Ta = 40°C to 125°C .. . Industrial Grade
© Ultrasmail Packaging
— 5-Pin SOT-23 (TLV2401)
— 8-Pin MSOP (TLV2402)
® Universal OpAmp EVM (Refer to the EVM
Selection Guide SLOU060)
description
The TLV240x family of single-supply operational
amplifiers has the lowest supply current available
today at only 880 nA per channel. Reverse battery
protection guards the amplifier from an over-
current condition due to improper battery
installation. For harsh environments, the inputs
can be taken 5 V above the positive supply rail
without damage to the device.
==
51052448 — FEBRUARY 2000 — REVISED NOVEMBER 2000
re
I cg - Supply Current — | A/Ch
Operational Amplifier
SUPPLY CURRENT
VS
SUPPLY VOLTAGE
1.4
Ay= 1
12. VIN=Ycc?2
TA= 25°C
1.0
0.8
0.6
0.4
0.2
0
0 2 4 6 8 10 12 14 16
Yee - Supply Voltage — Y
The low supply current is coupled with extremely low input bias currents enabling them to be used with mega-Q
resistors making them ideal for portable, long active life, applications. DC accuracy is ensured with a low typical
offset voltage as low as 390 pV, CMRR of 120 dB and minimum open loop gain of 130 V/mV at 2.7 V.
The maximum recommended supply voltage is as high as 16 V and ensured operation down to 2.5 V, with
electrical characteristics specified at 2.7 V, 5 V and 15 V. The 2.5-V operation makes it compatible with Li-lon
battery-powered systems and many micro-power microcontrollers available today including TI's MSP430.
All members are available in PDIP and SOIC with the singles in the small SOT-23 package, duals in the MSOP,
and quads in TSSOP.
SELECTION OF SINGLE SUPPLY OPERATIONAL AMPLIFIER PRODUCTST
V Vv BW SLEW RATE | lccich
DEVICE № im (MHz) (Vine) A) RAIL-TO-RAIL
TLv24oxt | 25-16 0.380 0.005 0.002 0.880 Vo
TLV224x 2.5-12 0.600 0.005 0.002 1 O
TLV2211 27-10 0.450 0.065 0.025 13 О
TLV245x 2.7-6 0.020 0.22 0.110 23 Vo
TLV225x 2.7-8 0.200 0.2 0.12 35 О
T Ali specifications are typical values measured at 5 V.
+ This device also offers 18-V reverse battery protection and 5-V over-the-rail operation on the inputs.
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
A
PRODUCTION DATA Information le current as of publication date.
Products conform to specifications per the terms of Texag Instruments
standard warranty. Production processing does not necescarily include
testing of all parameters.
“3 TEXAS
INSTRUMENTS
POST OFFICE BOX 655303 * DALLAS, TEXAS 75265 1
Copyright € 2000, Texas instruments Incorporated
TLV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/OUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
SLOS244B — FEBRUARY 2000 — REVISED NOVEMBER 2000
—_—_————
SA |
TLV2401 AVAILABLE OPTIONS
PACKAGED DEVICES
TA hile SMALL OUTLINET SOT-23t SYMBOLS | PLASTIC DIP
(D) (DBV) (P)
0°C to 70°C {500 TLV2401CD — | Tlvza01CDBV | vawe | —
-40°C to 125°C TLV24011D | TLV24011DBV VAWI || TLV24011P
T This package is available taped and reeled. To order this packaging option, add an R suffix to the part number (e.g.,
TLV2401CDR).
TLV2402 AVAILABLE OPTIONS
PACKAGED DEVICES
TA Mis SMALL OUTLINET MSOPt svmBoLs || PLASTIC DIP
(D) (DGK) (P)
0°C to 70°C = TLV2402CD {| TLv2402CDGK | TIA | —
—40°C to 125°C " TLV24021D | TLV2402IDGK TAY [| TLV24021P
T This package is available taped and reeled. To order this packaging option, add an R suffix to the part number (e.g.,
TLV2402CDR).
TLV2404 AVAILABLE OPTIONS
PACKAGED DEVICES
Vigmax
TA noise | SMALLOUTUINET | PLASTIC DIP TSSOP
(D) (N) (PW)
0°C to 70°C 1500 y TLV2404CD TLVZ404CN | TLV2404CPW
—40°С to 125°C и TLV24041D TLV2404IN TLV2404IPW
T This package is available taped and reeled. To order this packaging option, add an R suffix to the part
number {e.g., TLV2404CDR).
TLV240x PACKAGE PINOUTS
TLV2401
DBV PACKAGE
(TOP VIEW)
CuT [11 5
GND |2
IN+ - 13 4
NC — No intemal connection
| Vee
|] IN-
TLV2401
D OR P PACKAGE
(TOP VIEW)
Nc CI 1°
IN- ET
IN+ EI
GND ET
2 7
nat
4
8 LL] Nc
LD Vcc
117 QUT
5 LL) NC
TLV2404
D, N, OR PW PACKAGE
(TOP VIEW)
TOUT CL
1IN-L
1IN+ [IC
Усс 4
13 414/11 40UT
As 1] 4IN-
127 1] 4IN+
MEL GND
2IN+CI 5 OT] 3IN+
2IN-CH PE LL 3IN—
20OUT CE] 7
8ET130UT
TLV2402
D, DGK, OR P PACKAGE
{TOP VIEW)
GNDCO
11 Veo
17 20UT
1] 2IN-
CT) 2IN+
10UTCI]) 2 8
М-Н 5 7
11N+CC fe
4 5
4 TEXAS
INSTRUMENTS
POST OFFICE BOX 655303 € DALLAS, TEXAS 75265
TLV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/OUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
5.032448 — FEBRUARY 2000 — REVISED NOVEMBER 2000
om TE НН
absolute maximum ratings over operating free-air temperature range (unless otherwise noted)t
Supply voltage, Veo (see Note 1) ................. 2.200. ea eran ee Ce eee 17V
Differential input voltage range, Vip .................... ... PTE < ее к оеококжнб кожа ка но +20 V
Input current range, |; (any input) ................. ena df EL MEN DT. LE Mea ....... 10 MA
Output current range, lo ........... EE... EA. A AUN Mad al VE Sr SS FIOMA
Continuous total power dissipation ...... .... ............ LLL WER LLL. See Dissipation Rating Table
Operating free-air temperature range, Ta: Csuffix .......... Cava ER. EE. E... °C to 70°C
suffix ... ................. ....... .....—=40°Cto 125°C
Maximum junction temperature, Ty ................ KA WEE RE AO HA eee 150°C
Storage temperature range, Tstq ..... coo, SEE ea bl a Ju 65°C to 150%
Lead temperature 1,6 mm (1/ 16 inch) from case for 10 seconds ..... ... ..... ... CP 260°C
T Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device. These are stress ratings only, and
functional operation of the device at these or any other conditions beyond those indicated under “recommended operating conditions” is not
implied. Exposure to absoclute-maximum-rated conditions for extended periods may affect device reliability.
NOTE 1: All voltage values, except differential voltages, are with respect to GND
DISSIPATION RATING TABLE
OJC BJA TA = 25°C TA = 125°C
PACKAGE oom Com) POWERRATING POWER RATING
D (8) 38.3 176 710 mW 142 mW
D (14) 26.9 122.6 1022 mW 204.4 mW
DBV (5) 55 324.1 385 MW 77.1 mW
DGK (8) 54.2 259.9 481 mW 96.2 mW
N (14) 32 78 1600 mW 320.5 mW
P (8) 41 104 1200 mW 240.4 mW
PW (14) 293 173.6 720 mW 144 MW
recommended operating conditions
MIN MAX ; UNIT
Single suppl 25 16
Supply voltage, Yoco g PPY \
Split supply £1.25 +8
Common-mode input voltage range, VICR 0.1 Vco+5 \
Operating f ire ture T C-suffix 0 70 °C
rating free-air temperature,
perno Ре А l-suffix —40 125
4 TEXAS
INSTRUMENTS
POST OFFICE BOX 655303 ® DALLAS, TEXAS 75265 3
TLV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/OUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
SLOS244B — FEBRUARY 2000 - REVISED NOVEMBER 2000
= mar
electrical characteristics at recommended operating conditions, Voo = 2.7, 5 V, and 15 V (unless
otherwise noted)
dc performance
PARAMETER TEST CONDITIONS TAT MIN TYP MAX | UNIT
= 25°C 390 1200
VIO Input offset voltage YO = Усс \, pv
VIC = Vcc/2 Y, Full range 1500
avio Offset voltage draft Rs = 50 0 25°C 3 UVPC
25°C 63 120
Vee=27V
Full range 80
В . Vic = 0 to Vee, _ 25°C 70 120
CMRR Common-mode rejection ratio Vcc=5V dB
j Rg = 50 Q CC Fullrange | 63
25°C 80 120
Усс = 15Y
Full range 75
Vee =27V, V =1V, Rp =500kQ =. = ha
CC 74" 6 VOlpp) ” Full range 30
Large-signal differential voltage Ven=5V V =3V Ri =500kO 25°C 300 1000
; ; =3V, = ЗУ, = vimV
AVD amplification CC O(pp) L Full range 100
Vee=15V, VV =6V, Rp = 500 k2 A ==
CC "OP PL Fullrange | 120
T Full range is 0°C to 70°C for the C suffix and —40°C to 125°C for the | suffix. If not specified, full range is —40°C to 125<C.
input characteristics
PARAMETER TEST CONDITIONS Tat MIN TYP MAX| UNIT
25°C 25 250
ho Input offset current TLV240xC 300 pA
YO = Ycc2 Y TLV240xl Full range 400
eo м 25°С 100 300
IB Input bias current TLV240xC Full range 350 | pA
TLV240xI 900
i(d) Differential input resistance 25°C 300 MQ
Cicy Common-mode input capacitance f=100 kHz 25°C 3 pF
T Fuli range is 0°C to 70°C for the C suffix and —40°C to 125°C for the | suffix. if not specified, full range is —40°C to 125°C.
4 TEXAS
INSTRUMENTS
A POST OFFICE BOX 655303 ® DALLAS, TEXAS 75265
TLV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/QUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
SLOS244B — FEBRUARY 2000 — REVISED NOVEMBER 2000
= =~ ===
electrical characteristics at recommended operating conditions, Voc = 2.7, 5 V, and 15 V (unless
otherwise noted) (continued)
output characteristics
PARAMETER TEST CONDITIONS TAT MIN TYP MAX! UNIT
25% 2.85 288
Усс = 2.7 \
Ful range | 2.63
VIC = Vcc/2, _ 25°C 4.95 4.98
УСС = БУ
'ЮН = —2 нА Cs Full range | 4.93
25°C 14.95 14.98
Voc = 15 V
. Full range | 14.93
VoH High-level output voltage Vv
25°C 262 2.65
УСС = 2.7 \
Full range 2.6
= 25°C 492 495
МС = Усс? | усс= Бу
Юн = -50 нА Full range 4.9
25°C 14.92 14.95
УСС = 15 \
Full range 14.9
VIC =Vec/2. lol =21A 25°C 90 150
IC "CC OL Full range 180
VOL Low-level output voltage mv
VIC = Veci2, lor = 50 uA 25°C 180 230
cu 2 Full range 260
lo Output current Vo = 0.5 V from rail 25°C +200 HA
T Full range is 0°C to 70°C for the C suffix and —40°C to 125°C for the | suffix. If not specified, full range is —40°C to 125°C.
power supply
PARAMETER TEST CONDITIONS TAT MIN TYP MAX | UNIT
25°C 880 950
МСС = 2.7 М ог 5 \
| Supply current (per channel) YO = Усс/2 Full range 1290 A
u rren r = n
CC РРУ p O "CC - 25% 900 990
Vee=15V
Full range 1350
Vee =-18V, ViN=0V, -
Reverse supply current Vo = Open circuit 25°C 50 nA
Vec=2.7t05V, 25°C 100 120 dB
р UT В Vic = Vco/2 V, TLV240xC Full range 96
PSRR (AVEC/AVIO) 240х! 85 dB
Vcc=51015V Vic=Vcc? V, 25°C 100 120 dB
No load Full range 100
T Full range is 0°C to 70°C for the C suffix and —40°C to 125°C for the | suffix. If not specified, full range is —40°C to 125°C.
Y TEXAS
INSTRUMENTS
POST OFFICE BOX 655303 ® DALLAS, TEXAS 75265
TLV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/OUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
SLOS244B — FEBRUARY 2000 - REVISED NOVEMBER 2000
E
electrical characteristics at recommended operating conditions, Veo = 2.7, 5 Y, and 15 V (unless
otherwise noted) (continued)
dynamic performance
PARAMETER TEST CONDITIONS TA MIN TYP MAX UNIT
UGBW Unity gain bandwidth R, = 500 k&, CL = 100 pF 25°C 5.5 kHz
SR Slew rate at unify gain УО(рр) = 0.8 \, Rp =500kQ, Ср = 100 рЕ 25°C 2.5 Vims
M Phase margin 60°
? - © RL = 500 k0, CL = 100 pF 25°C
Gain margin 15 dB
Vcc=2.70r5V,
VisTEP)PP=1V, CL=100pF, [0.1% 1.84
| Ay=-1, Rp = 100 kQ
ts Settling time 25°C ms
Усс = 15 \, 0.1% 6.1
V(sTeEP)PP =1V. Cr =100 pF,
Ay =-1, RL =100kQ [0.01% 32
noise/distortion performance
PARAMETER TEST CONDITIONS TA MIN TYP MAX | UNIT
o | f=10 Hz 800
Vn Equivalent input noise voltage т= 100 Ну Sete ED nVAHz
la Equivalent input noise current f= 100 Hz 8 fANHZ
vi TEXAS
INSTRUMENTS
6 POST OFFICE BOX 655303 ® DALLAS, TEXAS 75265
TLV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/OUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
SLOS244B —- FEBRUARY 2000 — REVISED NOVEMBER 2000
U!
| ms
TYPICAL CHARACTERISTICS
Table of Graphs
FIGURE
Vio Input Offset Voltage vs Common-mode input voltage 1,2, 3
vs Free-air temperature 4, 6, 8
IR Input Bias Current =
vs Common-mode input voitage 5,7, 9
vs Free-air temperature 4 6,8
lo Input Offset Current
vs Common-mode input voltage 5,7,9
CMRR Common-mode rejection ratio vs Frequency 10
VOH High-level output voltage vs High-level output current 11, 13, 15
VOL Low-level output voltage vs Low-level output current 12, 14, 16
VO(PP) Output voitage peak-to-peak vs Frequency 17
Zo Output impedance vs Freguency 18
Ice Supply current vs Supply voltage 19
PSRR Power supply rejection ratio vs Frequency 20
AVD Differential voltage gain vs Frequency 21
I Phase vs Frequency 21
Gain-bandwidth product vs Supply voltage 22
SR Slew rate vs Free-air temperature 23
dm Phase margin vs Capacitive load 24
Gain margin vs Capacitive load 25
Supply current vs Reverse voltage 26
Voltage noise over a 10 Second Period 27
Large signal follower puise response 28, 29, 30
Small signal follower puise response 31
Large signal inverting pulse response 32, 33, 34
Small signal inverting pulse response 35
Crosstalk vs Frequency 36
VW Texas
INSTRUMENTS
POST OFFICE BOX 655303 ® DALLAS, TEXAS 75265
TLV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/OUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
SLOS244B — FEBRUARY 2000 — REVISED NOVEMBER 2000
me AE
INPUT OFFSET VOLTAGE
vs
COMMON-MODE INPUT
VOLTAGE
8
сс = 2.7 \
Ta = 25°C
8 2
8
8
Vio Input Offset Voltage — uv
Ра <
= =
oc
—200
—D.1 0.20 0.60 1.00 1.40 1.80 2.20 280 2.5
Vicr = Commen-Mode Input Voltage — Y
TYPICAL CHARACTERISTICS
INPUT OFFSET VOLTAGE
vs
COMMON-MODE INPUT
VOLTAGE
100
Eo
&
4
© -100
E —200
Ë
o -300
> Yoco =5Y
Ta=25°C
=400 : : :
0104 10 16 22 28 34 40 46 52
VicR - Common-Moade input Voltage — Y
Figure 1 Figure 2
INPUT BIAS 7 OFFSET CURRENT
INPUT BIAS / OFFSET CURRENT YS
vs COMMON MODE INPUT
FREE-AIR TEMPERATURE VOLTAGE
800 400
® soul Vec=27v ñ 350 |— Voc=27V
, Vic = 1.35 V ® 200 |- ТА=25°С
Ë Ë
E 400 E 250
= 300 : 200
: 200 O 150
$ $ 100
= om
= 100 5 Y 50 40
Ë © Е 0
5 hg o -50
= 7100 = —100 lie
= т —150
- 40-25-10 5 20 35 50 65 80 95 110125 1 02 06 10 14 18 22 2829
TA — Free-Air Temperature — °C VICR - Common Mode Input Voltage - V
Figure 4 Figure 5
INPUT BIAS / OFFSET CURRENT
vs INPUT BIAS / OFFSET CURRENT
COMMON-MODE INPUT vs
VOLTAGE FREE-AIR TEMPERATURE
200 700
ê Vec=3V â 600 -- Yec=15V
& MO TA=25C = Vic=75V
В i Е SCO
5 100 a
2 400
: 50 Ё 300
= ® 20
3 в
109
É © Ë
Y I 0
o
9-100 = 100
= |
„® —150 2 200 =
-0.1 04 10 16 22 28 34 40 46 52 40-25-10 5 20 35 50 65 80 95 110125
VICR - Common Mode Input Voltage — Y Ta — Free-Air Temperature - °C
Figure 7 Figure 8
I ——
Y TExas
INSTRUMENTS
8 POST OFFICE BOX 655303 € DALLAS, TEXAS 75265
INPUT OFFSET VOLTAGE
УЗ
COMMON-MODE INPUT
VOLTAGE
400
Voc=15V
Ta = 25°C
300
Input Offsat Voltage — JV
I
o
< ao |
o
Do
©
o
> 300
400
01 20 42 64 86 108 130 152
Vicr — Common-Mode Input Voltage —V
Figure 3
INPUT BIAS / OFFSET CURRENT
vs
FREE-AIR TEMPERATURE
3 Voo=6V
= Vic=25V
Ё
|
5
m
2 10
Е
o Iie
a
_ 40-25-10 5 20 35 50 65 80 95 110125
TA — Free-Alr Tamparature — °C
Figure 6
INPUT BIAS 7 OFFSET CURRENT
vs
COMMON-MODE INPUT
VOLTAGE
250
2 200 УСС = 15 \
e Ta = 25"C
ЕЁ 150
Oo
Ё 100
- 50
a
ma 0
5
=
5 —50
2 -100
©
—150
=0.1 20 42 84 86 108 13.0 152
VICR = Common-Mode Input Voltage —V
Figure 9
TEV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/QUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
SLOS244B — FEBRUARY 2000 — REVISED NOVEMBER 2000
m
TYPICAL CHARACTERISTICS
COMMON-MODE REJECTION RATIO
VS
FREQUENCY
HIGH-LEVEL OUTPUT VOLTAGE
vs
HIGH-LEVEL OUTPUT CURRENT
LOW-LEVEL OUTPUT VOLTAGE
vs
LOW-LEVEL OUTPUT CURRENT
POST OFFICE BOX 655303 ® DALLAS, TEXAS 75265
E 120 2.7
> NN 7 > Усс = 2.7 \
o = 1
3 100 8 al 0 A 5 TA=25
< a ’ 2 TA - 0°C
© 80 = Ta = 40% = TAF
Bl — ;
; |
3 60 o Ta ==0°C 4 o
г лв 2. 3 TA= 70°C
40 3 TA= 70°C Ta = 125°C
Е 5 Тд = 125 °С Ё
=
1.5 )
3 20 z 5
с > >
50 12
1 10 100 ik 10k 0 50 100 150 200 0 50 100 150 200
f - Frequency — Hz IOH — High-Lavel Output Current — LA loL = Low-Level Output Current — uÂ
Figure 10 Figure 11 Figure 12
HIGH-LEVEL OUTPUT VOLTAGE LOW-LEVEL OUTPUT VOLTAGE HIGH-LEVEL OUTPUT VOLTAGE
vs vs vs
HIGH-LEVEL OUTPUT CURRENT LOW-LEVEL OUTPUT CURRENT HIGH-LEVEL OUTPUT CURRENT
1.50 15.0
ey
> > Vec=5V > = —
a 9 1.25
2 S TA=0°C Ë 14.5
S 1.00 Ta = —40°C $
8 E | E Тд = -0°С
© Тд = 25 °С q 0781 тд=25 °С О 14.0 |- Тд=25°С
А = T =
3 TA =70 °С | 8 TA В 70 °C С a =
z Ta = 125 °С | 5 0.50 [— TA=125°C 5 |
т 3.5 = 13.5 Ta = 40°C
y аз
5 | > 3 Усс = 15V |
3.0 0 13 :
0 50 100 150 200 a 50 100 150 200 0 50 100 150 200
loH — High-Level Output Current — pA lo, = Low-Level Output Current — pi lox = High-Level Output Current - pA
Figure 13 Figure 14 Figure 15
OUTPUT VOLTAGE
LOW-LEVEL OUTPUT VOLTAGE PEAK-TO-PEAK OUTPUT IMPEDANCE
vs vs vs
LOW-LEVEL CUTPUT CURRENT FREQUENCY FREQUENCY
1.50 | > :
> Voc = 15V x SAR es
I 1.25 vee = 15 \
В ШИ q
8 100 | tae Y 3 :
5 Тд = DC 8 3
0.75 Ta = 25 °С a E
5 Ta = 70°C $ 1
Ta = 125 °С 5 RL = 100 ко
Ë 0.50 g CL = 100 pF o
1 O TA = 25°C a
3 025 ' N
> o Усс; = 2.7, 5, & 15 М
9 S TA = 25°C
0 50 100 150 20 10 100 1K 100 1k 10k
loL - Low-Lavel Output Current - pA f - Frequency — Hz f - Frequency = Hz
Figure 16 Figure 17 Figure 18
DL. |
di TExas
INSTRUMENTS
TLV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/QUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
SLOS244B — FEBRUARY 2000 - REVISED NOVEMBER 2000
III
TYPICAL CHARACTERISTICS
SUPPLY CURRENT POWER SUPPLY REJECTION RATIO
vs
SUPPLY VOLTAGE FREQUENCY
Ta = 125°C
Ta = 70°C
Ta = 25°C
TA=0"C
Ay=1 Ta =—40°C
VIN = Yoo 12
0 2 4 6 5 10 12 14 16
Усс = Supply Voltage — Y
Figure 19
leg - Supply Current — y A/Ch
DIFFERENTIAL VOLTAGE GAIN AND PHASE
vs
FREQUENCY
ao
TU
|
=
a
8 a
8
= :
e
Е
a 4
‘ RL = 500 КО
$ C, = 100
10 100 1k 10k
f - Frequency — Hz
Figure 21
SLEW RATE
vs
FREE-AIR TEMPERATURE
3.5
3.0
= 5, 15
E 25 Vec=5,1
i
5 2.0
3 1.5
1
5 1.0 SR— Veo =2.7,5,6 15 V
0.5
0
40-25-16 5 20 35 50 65 80 95 110125
Ta - Free-Alr Temperature - °C
Figure 23
4 TEXAS
INSTRUMENTS
PSRR - Powar Supply Rejection Ratio - dB
GBWP -Gain Bandwidth Product — kHz
Phase Margin - °
—
ha
a
—
=
a
8
Vec=27,5,415V
TA = 25°C
©
©
=]
=
60
50
40
10 100 fk 10k
f - Fraquency — Hz
Figure 20
GAIN BANDWIDTH PRODUCT
vs
SUPPLY VOLTAGE
7
Ta = 25°C
8 RL = 100 kG
CL = 100 рЕ
5 f=1kHz
4
3
2
1
0
25 40 55 70 8.5 10,0 11.5 13.0 14.5 16.0
Vee — Supply Voltage —V
Figure 22
PHASE MARGIN
VS
CAPACITIVE LOAD
Мсс = 2.7, 5, & 15 \
R| = 500 kQ
Ta = 25°C
10 100 1k 10k
CL — Capacitive Load - pF
Figure 24
10 POST OFFICE BOX 655303 * DALLAS, TEXAS 75265
TLV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/OUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
й SLOS244B — FEBRUARY 2000 — REVISED NOVEMBER 2000
FE
TYPICAL CHARACTERISTICS
GAIN MARGIN SUPPLY CURRENT
VS vs
CAPACITIVE LOAD REVERSE VOLTAGE
25 TT TTT 60
RL =500kQ | Й 55
TA=25°C | | И TA = 25°C
20 > 50
| pet | ® 45
|
3 ле TI || Vec=18v = 40
= ei | | Ё 35
Е | © 30
= | =
= 10 | a 25
Vcc =2785V ' 15
| | | | 5
0 BH | i | 0
10 100 1k 10k —18 16-14 -12-10 8 + 4 2 0
CL - Capacitive Load — pF Veo - Reverse Voltage — V
Figure 25 Figure 26
VOLTAGE NOISE LARGE SIGNAL FOLLOWER
OVER A 10 SECOND PERIOD PULSE RESPONSE
4 FF 2
Veg =5V
3 f=01{Hzto 10Hz —
2 TRS
a 2 J | > >
3 | ! gi
2 $ Ay = 18
$ 0 = RL = 100 ka
E a CL = 1000F 2
A 5 Me E 7 8 TA = 25°C =
$ й du I o EZ
5 ! !
Ë
= |
0 1 2 3 4 5 8 7 8 8 10
t—Time-s t= Time — ms
Figure 27 Figure 28
LARGE SIGNAL FOLLOWER LARGE SIGNAL FOLLOWER
PULSE RESPONSE PULSE RESPONSE
15
Усс = БУ \СС = 15 \
Аут! Ау= 1 10
В; = 100 КО RL = 100 kQ
> CL = 100 рЕ > > CL = 100 pF в >
I TA = 25°C 1 1 TA = 25°C !
Es с $ &
Ba В S 0 =
3 5 $ $
g 3 5 5 5 +
Eg, E 5 É
© I o I
1 = 1 =
„D 1 a JD >
0
0 2 4 6 8 10 12 14 16
t- Time — ms t- Time - ms
Figure 29 Figure 30
EE
INSTRUMENTS
POST OFFICE BOX 855303 ® DALLAS, TEXAS 75265
11
TLV2401, TLV2402, TLV2404
FAMILY OF 880-nA/Ch RAIL-TO-RAIL INPUT/QUTPUT
OPERATIONAL AMPLIFIERS WITH REVERSE BATTERY PROTECTION
SLOS244B — FEBRUARY 2000 — REVISED NOVEMBER 2000
Vo - Output Voltage — mv
Vo- Output Voltage — mV
= Qutput Voltage — Y
£20
_
TYPICAL CHARACTERISTICS
SMALL SIGNAL FOLLOWER LARGE SIGNAL INVERTING
PULSE RESPONSE PULSE RESPONSE
300 3
VIN 150 VIN >
° E > 1
= fogs | eo |
100 ин 3 3 0.5 vee > Vv 0 3
a0 Ry = 100 ka 5 ® 00 RL = 100 ke -1 8
CL=100 pF = 2 CL = 100 pF =
50 TA = 25°C a 8 05 Ta = 25°C E
49 т o x
20 = 1.0 { =
o 15 о
—2
0 100 200 1300 1400 1500 0 1 2 3 4 5 6 7
t- Time — us t= Tima - ms
Figure 31 Figure 32
LARGE SIGNAL INVERTING LARGE SIGNAL INVERTING
PULSE RESPONSE PULSE RESPONSE
a 12
3 9
2 VIN 6
т > 3
0.5 о! A Voc=15V a
0.0 —1 g ë 2 Ау =-1 + q
В : roues
—1.0 y —2 L= oP =
ge 5 Ta = 25°C a
-1.5 1 6 -4 =
z 9-6 =
—2,5 Vo —8 Vo
—3.0 —10
-3.5 —12
O 1 2 3 4 5 6 O 5 10 15 20 25 30 35
t - Time - ms t — Time - rm
Figure 33 Figure 34
CROSSTALK
SMALL SIGNAL INVERTING vs
PULSE RESPONSE FREQUENCY
0
VIN МСС = 2.7,
-20 |- 5, & 15 М
All Channels
Voc=2.7,5, E 40 | RL=100k0
& 15V I Cz = 100 pF Voc = 15 V
Ay =—1 © 7 go |- VIN=1
RL = 100 ko 3 -
CL = 100 pF 5
Ta = 25°C ê $ 80
т © «vol Мос = 2.7, 5\
о > 120
—140
0 200 400 600 800 1000 1200 10 100 1k 10%
t - Time - ms f — Frequency —Hz
Figure 35 Figure 36
12
4 TEXAS
INSTRUMENTS
POST OFFICE BOX 655303 ® DALLAS, TEXAS 75285
Universitat de Vic ntr . gr . sí.
UV] C Escola Politécnica Control de la temperatura ¡ el llum mitjangant dispositius sense fils
Superior Ramon Altarriba Roca
LCD GDM1602K
XIAMEN OCULAR
13.5<max>
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t= mere Mechanical Data
1. ofs with cursor ED a Cm =
m Standard ini
2. Built-in controlier (KS0066U or Equivalent) 7 — m hsion ser = = An
3. +5V power supply(Also available for +3.0V) — — dba
4. 1/16 duty Viewing area 64.5x16.4 mm
5. BKL to be driven by pin1,pin2,or pin15,pin16,or A,K Dot size 0.56x0.61 mm
6. N.V.optional Character size 3.00x5.23 mm
is Symbol = i= = Absolute Maximum Rating
or Aa Filan тн et A TE Че: a AE 7 Standard
1 vss | GND item | Symbol {Ere a] unt
2 VDD +5V Power supply VDD-VSS | -0.3 —— 5.5 y
Input voltage vi -0.3 — VDD
3 VO Contrast adjustment
Electronical characteristics
4 RS H/L Register select signal =—— Hina
Item Symbol | Condition Slandard Unit
5 RW H/L Read Write signal = tes A Min] Typ | Max |
H/L Enable signal i ol LT Jo LSE |
6 E > rputwitege | VOD esa | 27 | зо | 53 | v
7 peo | H/L Data bus line Supply current | io | von=5vV!-— | 15 | 4 | ma
-20°C | ------ == | ----- -
8 DB1 H/L Data bus line Recommended = " В =
; LCD riling voltage _ : : :
9 DB2 | VL Data bus line for normal temp || овес | 43 | 45 | 47 | Vv
10 DB3 | H/L Data bus line pari 50°C | 41 | 43 | 45
H/L Data bus line Me | |— р
11 DB4 | LED forward voltage] VF | 25°C |-— | a2 Tas | v
12 DB5 | HL Data bus line \LED forward current| IF 25°C | ] 120 | 160 | mA
| EL i EL=
13 pgs | L Data bus line EL power supply | 1g | ee | — | —|— A
14 DB7 HIL Data bus line Display character address code:
+4 2V for LED Display position
15 A 1 2 34567 809 10 11 12 13 14 15 16
16 K Power supply for BKL(OV) DDRAM address 00 01 02 — — — — =
DDRAM address 40 41 42 — — — — —
Universitat os Ye Control de la temperatura i el it ispositi
UVIC Escola Políticnica a temperatura i el llum mitjancant dispositius sense fils
Superior Ramon Altarriba Roca
ARDUINO ETHERNET
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Astarenza Designs ARE PR.OVIDEDO "AS IS” AND "WITH ALL FALILTS, Ardumo DISCLAIMS ALL OTHER WARRANTIES, EXPRESS OR IMPLIED,
F=GARDING PRODUCTS, INCLUDING BLT NOT LIMITED TO, ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PUAPOSE
Ardulno may make changes (0 spa isatons and product de-edptons at time, withow notica. The Cuctomer must mot
rely on the absence or chamac i. Jos of any lasture : or instruatane m "It served” or "undefined." Arduino reserves
Ihese lar future dafinhion and ahall have na lly wi for son METE or Incompaeniitias ardaing Mom future changes to them.
The product informaron an the Web Site or Materials ls subject ho chenge vithout notica. Do not ingiiza e design with this Information.
"ARQUINO" is a registerad trademark
Universitat ge Vic Control | m r rai yr , "ga ,
UVI C Ea de la temperatura i el llum mitjancant dispositius sense fils
Superior Ramon Altarriba Roca
ARDUINO USB2SERIAL
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Reference Designs ARE PROVIDED ”AS IS” AND “WITH ALL FAULTS. Arduino DISCLAIMS ALL OTHER WARRANTIES, EXPRESS OR IMPLIED,
REGARDING PRODUCTS, INCLUDING BUT NOT LIMITED TO, ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE
Arduino may make changes to specifications and product descriptions at any time, without notice. The Customer must not
rely on the absence or characteristics of any features or instructions marked “reserved” or “undefined.” Arduino reserves
these for future definition and shall have no responsibility uhatsoever for conflicts or incompatibilities arising from future changes to them.
The product information on the Web Site or Materials is subject to change without notice. Do not finalize a design with this information.
ARDUINO is a registered trademark
Universitat de Vic Control de la temperatura ¡| el llum mitjancant dispositius sense fils
UVIC i a Ramon Altarriba Roca
XBEE SHIELD
IN OUT
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ММС сес, Control de la temperatura i el llum mitjancant dispositius sense fils
Superior Ramon Altarriba Roca
XBEE EXPLORER
3.37
R3
0108
DIC1
0102
DIN3
RTS
DIOS
RES
0109
CTS
0104
A
Ul
—0+ 16 1
ED us =A X 15] USD Ty
— [GND au т 22 UCC CTS O LIS
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C14 Ci1 26 TEST
AGND
G.LuF | B.1uF 7 GND1
18
54 | 6ND2 TXLED
GND GND GND ENDS RXLED
—_ FTZ232RL
GND LED3
Green
JP? 3,30
J GND 1 U2
110 3.3 | 1
“Ta NOUT > OUT
ls DIN 3 | DIN
17 DIO12 4 | 91017
LE —
„15 RSSI 6 pes]
E E 01011 2 | Dio
HE RFS1 8 | рес
=? OTR ~~ 95 OTR
„|1 GND „1951 сыр
|
GND
BU
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+ с < м
С’ | © СЕ] ="
+ 6 +
VO! VOS
JD “ Jo
GND GND
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au IN OUT
GMO CZ
| | EN gp |= |10UF) B.1uF
GND 330 GND GND
22 poa a]
19 DIM 2 |
18 paz 31
17 0103 “|
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15 _ DIOS él.
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12 CIS al
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EU 11 81
JP3
COEN
TITLE: XBee-Explorer-v12 SFE
Document Number: REV:
Date: 6/3/2008 2:30:07 PM
Sheet: 1/1
UVI C ¿niverstat dvi Control de la temperatura i el llum mitjangant dispositius sense fils
Superior Ramon Altarriba Roca
XBEE
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