Custom Resistor Networks Solutions
Application specific resistor networks are readily available from CTS to
provide the designer with optimum performance and cost effective solutions.
There are no
tooling or engineering charges to supply resistor networks with application
specific schematics. Lead times for application specific networks are the same
as for standard manufactured product. Application specific networks are
available in 752, 753, 766, 767, and 768 products.
- Customer part number to maintain design confidentiality.
- Multiple and/or non-standard resistor values.
- Resistor networks designed for low capacitance or inductance.
- Non-standard tolerances or matching requirements. Non-standard schematics.
Resistor values, tolerance, TCR, power rating, and circuit connections are
the factors which determine the resistor network design to meet the circuit
designers optimum performance and cost goals.
The following information is provided to assist you in specifying application
specific networks which meet performance requirements at the lowest cost.
- Similar resistor values should be grouped on a resistor network. Each
group of resistor values may require a different resistor ink formulation.
Normally a larger range of resistor values can be obtained in a single
resistor ink if the pin-outs are selected by the network designer.
- Usually three resistor ink formulations are the maximum that can be used
on a network. Each formulation required does increase the cost.
- The power dissipation of each resistor should be specified based on the
performance requirements. The total power must conform to the maximum
package power specification unless it is specified which resistors are
operated at a given time.
- Maximum operating voltage should be specified for each resistor when the
resistor value is high enough to supersede the power rating.
- Crossovers should be avoided. If necessary, a second level is provided by
utilizing the opposite side of the substrate surface.
- The TCR of each resistor is affected by the geometry of the resistor and
the number of resistor formulations required. TCR tracking between resistors
screened at the same time is dependent on the comparative resistor length.
TCR of ±200 PPM is considered standard for multiple formulation networks or
resistors of 100 ohms or less.
- Buried nodes should be avoided. Resistance values must be read with
special test equipment that may result in reduced measuring accuracy.
- The tolerance of each resistor should be specified based on the circuit
requirements. Resistor tolerance of ±2% is standard for all product.
- Consult with the factory prior to finalization of application specific
networks to obtain the optimum network design.
- The table below shows general empirical rules which usually apply to
application specific schematics. Actual capabilities are dependent on the
required schematic and should be verified by CTS.
|
Capability Guidelines |
face="Arial">Resistance Ranges |
|
Characteristics for Thick Film Networks |
10-20
Ohm |
31-99
Ohm |
100-1Meg
Ohm |
| Best Absolute Tolerance |
±0.3Ohm |
±0.3Ohm |
±0.25% |
| Ratio Match (50:1 max ratio)* |
±0.3Ohm |
±0.3Ohm |
±0.25% |
| Parallel Circuit Resistance Tolerance(>50:1
ratio* in Loop) |
±0.3Ohm |
±0.3Ohm |
±0.25% |
| Parallel Circuit Resistance Tolerance(<50:1
ratio* in Loop) |
±0.3Ohm |
±0.3Ohm |
±0.25% |
| Best TCR (-55C to +125C) |
±200PPM |
±100PPM |
±100PPM |
| Best TCR Tracking <3:1 ratio* (Same
ink/same side) |
75PPM |
50PPM |
50PPM |
| Best TCR Tracking >3:1 ratio* (Same
ink/same side) |
100PPM |
75PPM |
75PPM |
Maximum Resistor Power
(Not to exceed maximum package power) |
2 X (total package power)
(Total number of resistors)*
Highest Resistance Value = Ratio
Lowest Resistance Value
|
CTS -1 Bussed Schematic
The bussed schematic consists of (N-1) resistors (with N= to the number of pins)
of the same value connected to a common buss. These networks are commonly used
as pull up/pull down resistors or as impedance matching terminating resistors.
They can also be used in other applications where the circuit requires a number
of the same value resistors connected to a common point.
CTS -3 Isolated Schematic
The isolated schematic consists of (N/2) resistors of the same value which are
electrically isolated from each other. Normally these networks are used as
current limiting resistors and termination resistors. They can also be used in
other applications where the circuit requires a number of the same value
resistors which connect to various points. Since all resistors on the same
network are processed identically, the isolated networks have been used to
fabricate very accurate voltage dividers at low cost by selectively connecting
the resistors in series.
CTS -5 Dual Terminator Schematic
The dual terminator schematic consists of (2N-2) resistors of two different
values with each resistor value connected to a common buss. The resistor values
form standard Thevenin equivalent resistance values which are used for
termination to two different voltages. These networks are typically used for ECL
termination.
CTS -7 R/2R Schematic
The R/2R ladder network is commonly used for digital to analog or analog to
digital conversions by successive steps. The input signals are applied at each
bit of the ladder and the signal is taken from the output terminal where the
signal is used to drive an operational amplifier. R/2R ladder networks are
available with a ladder accuracy of ±1/2 LSB (least significant bit) up to a
maximum of 8 bits and ±1 LSB for 9 bits.
|
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