Labsmith HVS488 High Voltage Sequencer
The LabSmith HVS448 High Voltage Sequencer provides eight high-voltage channels with programmable sequencing for an entirely new level of high voltage control. With innovative voltage supply, voltage sensing, current supply, current sensing, and a ground-breaking sequencing environment, the HVS448 integrates your entire experiment, simply and safely.
HVS448 High Voltage Sequencer
The LabSmith HVS448 combines eight channels of high-voltage supply, precision current and voltage sensing, and a groundbreaking sequencing environment for an entirely new level of voltage manipulation. This system provides complete experiment control for microfluidics, MEMS, piezo-electronic actuators, and more.
MEMS and microfluidic research require a precise high-voltage supply, with coordinated switching of multiple high voltage channels. Open-loop voltage or current control is not good enough. The supply must be able to sense and react in real time.
The LabSmith HVS448 High Voltage Sequencer supplies eight high-voltage channels, with programmable sequencing for an entirely new level of voltage manipulation. With innovative voltage supply/sensing, current supply/sensing, and a ground-breaking sequencing environment, the HVS448 integrates your entire experiment, simply and safely.
Highlights
- Eight channels supplying/sensng up tp ±4 kV / ±6 mA
- 1 kHz sequencing for microfluidics and MEMS
- 16 bit current-sensing resolution
- Complete experiment control for microsystem analysis
Innovative Voltage Control
The HVS448 includes eight high-voltage channels, each of which can switch in a millisecond between several functions:- supply voltage with 100 mV resolution, while monitoring current with 300 nA resolution
- supply current with 300 nA resolution, while monitoring voltage with 100 mV resolution
- function as a high-voltage voltmeter with 200 M-Ohm input impedance.
Model | Max voltage differential |
Output voltage | Voltage monitor resolution (mV) | Max current (mA) | Current monitor resolution (nA) |
8000D | 8000 V | -4000 V to +4000V | 150 | 2.5 | 250 |
6000D | 6000 V | -3000 V to +3000 V | 100 | 3.2 | 300 |
3000 | 3000 V | -3000 V to 0 V -1500 V to +1500 V 0V to 3000 V |
100 | 6 | 300 |
3000D | 3000 V | -1500 V to +1500 V | 50 | 6 | 500 |
1500 | ±1500 V | -1500 V to 0 V -750 V to +750 V 0 V to 1500 V |
50 | 12 | 500 |
800 | ±800 V | -800 V to 0V -400 V to +400 V 0 V to 800 V |
25 | 25 | 1000 |
400 | ±400 V | -400 V to 0 V -200 V to +200 V 0 V to 400 V |
12 | 50 | 2000 |
200 | ±200 V | -200 V to 0 V, -100 V to +100 V, or 0 V to 200 V |
6 | 100 | 4000 |
Low-current models -LC
The HVS488 is availabl in a low-current model, with current resolution and maximum value reduced by a factor of 20. The LC models are suited for work with nanochannel structures with very high resistance
Model | Max voltage differential |
Output voltage | Voltage monitor resolution (mV) | Max current (mA) | Current monitor resolution (nA) |
8000D -LC |
8000 V | -4000 V to +4000V | 150 | 0.13 | 13 |
6000D -LC |
6000 V | -3000 V to +3000 V | 100 | 0.16 | 15 |
3000 -LC |
3000 V | -3000 V to 0 V -1500 V to +1500 V 0V to 3000 V |
100 | 0.3 | 15 |
3000D -LC |
3000 V | -1500 V to +1500 V | 50 | 0.3 | 25 |
1500 -LC |
±1500 V | -1500 V to 0 V -750 V to +750 V 0 V to 1500 V |
50 | 0.6 | 25 |
800 -LC |
±800 V | -800 V to 0V -400 V to +400 V 0 V to 800 V |
25 | 1.3 | 50 |
400 -LC |
±400 V | -400 V to 0 V -200 V to +200 V 0 V to 400 V |
12 | 2.5 | 100 |
200 -LC |
±200 V | -200 V to 0 V, -100 V to +100 V, or 0 V to 200 V |
6 | 5 | 200 |
Unique Sequencing Environment
The key HVS448 innovation is its ability to switch channels rapidly through different modes and settings, based on real-time calculations, measurements, or programmed sequences. Sequence(tm) software provides the flexibility and simplicity for creating sophisticated, adaptable, and fault-tolerant active controls.
The Sequence architecture simplifies control-system programming by dividing control over three levels:- A top-level "Sequence" program controls the flow between steps, including the conditions for changing steps and handling exceptions.
- Individual "Step" programs define channel functions. Each step can respond to timers, triggers, current or voltage levels, or real-time calculations. It can then switch regulation modes, alter voltage or current settings, and/or send digital output signals for any/all channels.
- "Trigger" programs describe how channels communicate with each other and external equipment. Each channel can be programmed to trigger based on any logical combination of channel outputs and/or external inputs.
Complete Experiment Control
An example microfluidic experiment helps explain the flexibility and power of the HVS448. To control this experiment, one HVS448 can automatically perform all of the following duties:- Detect a current dip as a cell passes through an orifice
- Convey that cell to a preparation chamber, then lock it in place
- Flow labeling dyes into the chamber and lyse the cell
- Inject the labeled lysate into a column
- Fractionate it into bands
- Power a photo-multiplier tube to detect fluorescence
- Trigger data recorders and cameras
- Flush the chamber, then await more cells.
SKU | LS-HVS488 |
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Manufacturer | LabSmith |
Country of Origin | USA |
Harmonized Code | 85372000 |