ライフサイエンスコーパス: equivalent circuit

1 d at various intervals and analyzed using an equivalent circuit.

2 llows analysis of complicated changes of the equivalent circuits.

3 observed impedimetric effect we performed an equivalent circuit analysis as well as analyzed the role

4 Equivalent circuit analysis indicated that electron tran

5 The proposed methodology requires no equivalent circuit analysis or data fitting and is equal

6 lified) and non-faradaic assays, requires no equivalent circuit analysis or prior assumption of respo

7 By using a one-dimensional capacitive equivalent circuit and a resonant tunneling model, this

8 electrical resistance (TEER), by fitting an equivalent circuit and by analyzing the single character

9 e fitting in order to obtain electrochemical equivalent circuit and corresponding circuit parameters

10 ad to cancer are abstracted as faults in the equivalent circuit and the Boolean circuit model is then

11 , it allows for the analysis of more complex equivalent circuits as associated with the presence of n

12 d ionic-electronic conductors, we propose an equivalent circuit based on transmission line model (TLM

13 As a result, functionally equivalent circuits can produce similar activity despite

14 ional resistance of the Butterworth-Van Dyke equivalent circuit) can be measured simultaneously.

15 on SWCNT surface provides unique changes in equivalent circuit components for each PFAS, i.e., chang

16 y a three-element circuit (i.e., the minimal equivalent circuit) comprised of two resistors and one c

17 ental viewpoint, the direct applicability of equivalent circuit concepts borrowed from microwaves is

18 The impedance data were fitted to an equivalent circuit consisting of a series resistor (R(S)

19 d the behavior of the IDA microelectrode, an equivalent circuit, consisting of an ohmic resistor of t

20 emitter excited state produce an optical ac equivalent circuit current, I(o) = qomega|x(o)|/d, feedi

21 s modeled with either a Helmholtz or Randles equivalent circuit (depending on the SAM used) in which

22 aic contributions present within an improved equivalent circuit description of such interfaces, it is

23 A network equivalent circuit element is derived to include the eff

24 The variable topology equivalent circuit element model of the nanocapillary is

25 ack of correlation evident between V(on) and equivalent circuit element parameters commonly associate

26 A simple, ultra-wide frequency range, equivalent circuit for plant cell suspensions is present

27 Our model consists of a Hodgkin-Huxley-type equivalent circuit for the sarcolemma, coupled with a fl

28 An equivalent circuit for the SECM cell and membrane is pro

29 f the electrical parameters that define this equivalent circuit in bulge, transition and mature RGCs.

30 An electrical equivalent circuit is derived for the electrospray proce

31 mplexity and thermodynamics for functionally equivalent circuits, making the physics-inspired approac

32 Using an equivalent circuit mimicking simultaneous whole-cell vol

33 We develop an equivalent circuit model and introduce a mutual inductan

34 unit cell including L-shaped grooves and its equivalent circuit model are introduced.

35 imulating the photocurrent responses with an equivalent circuit model containing a chemical capacitan

36 model for the sensor surface and the Randles equivalent circuit model for interfacial impedance.

37 An equivalent circuit model for the cell with the resonator

38 The equivalent circuit model for tissue resistance between t

39 An equivalent circuit model is established, and the simulat

40 ement with the theoretical analysis using an equivalent circuit model of the new FBAR structure.

41 The macroscopic model consists of an equivalent circuit model of the tethered membrane, and a

42 The obtained EIS spectra were fitted with an equivalent circuit model successfully explaining the imp

43 this paper, we provide an elegant yet simple equivalent circuit model that captures the complex, thre

44 we used impedance measurements to develop an equivalent circuit model that closely mimics the behavio

45 We additionally present an equivalent circuit model that combines the EIS data to c

46 e in excellent qualitative agreement with an equivalent circuit model that considers how magnetic pro

47 ent model of the nanocapillary is used in an equivalent circuit model that included contributions fro

48 We present an equivalent circuit model to describe resistive component

49 Moreover, we used an adapted equivalent circuit model to get a deeper understanding f

50 We propose an equivalent circuit model to minimize electrode polarizat

51 t, and in so doing, a full validation of the equivalent circuit model utilized, but also facilitates

52 An equivalent circuit model was developed to simulate this

53 d from impedance measurements, an electrical equivalent circuit model was developed.

54 By fitting the data to an electronically equivalent circuit model, cell-related parameters (cell

55 are generated and automatically fit into the equivalent circuit model, which is established using ele

56 and intrinsic parameters are extracted using equivalent circuit model, which is verified by the good

57 response is readily understood via a simple equivalent circuit model.

58 ivity measurements together with the Randles equivalent circuit model.

59 We derive a lumped-element, equivalent-circuit model for the thickness-shear mode (T

60 the measured frequency responses based on an equivalent-circuit model.

61 Equivalent circuit modeling is used to extract the cell

62 hydrogel membrane resistances extracted from equivalent circuit modeling of electrical impedance spec

63 n in the impedance data obtained by EIS, and equivalent circuit modeling of the electrodes composed o

64 An equivalent circuit modeling-based approach indicates tha

65 h standard viability Blue assay and EIS with equivalent circuit modeling.

66 s limitation, we introduce an approach where equivalent circuit modelling (ECM) on reference multiele

67 ized titanium electrodes as derived from the equivalent-circuit modelling of full-range impedance spe

68 V, and kinetic parameters based on electrode-equivalent circuit models are obtained as functions of C

69 CPEs have been introduced in equivalent circuit models, sometimes without solid justi

70 e impedance data are interpreted by designed equivalent circuit models.

71 his connection to design simple but accurate equivalent circuit models.

72 ectra that cannot be analyzed with classical equivalent circuit models.

73 y fitting the impedance spectra to a Randles equivalent circuit, one can demonstrate that the charge-

74 t of the impedance minimum of the electrical equivalent circuit or of the corresponding frequency.

75 d that when we performed PCA of the measured equivalent circuit parameters and the solubility and dip

76 erate transducer design criteria in terms of equivalent circuit parameters for broadband impedance ma

77 on pores during degranulation, tracking many equivalent circuit parameters simultaneously.

78 system can be analyzed to track down all the equivalent circuit parameters.

79 By employing the equivalent circuit representation suggested by these mod

80 t during the behavior, and assessment of the equivalent circuit, reveal the effectiveness of the beha

81 An equivalent circuit that models the impedance response of

82 pproach with point-contact loading and Mason equivalent circuit theory.

83 The results allowed each variable in the equivalent circuit to be estimated.

84 d using the case of the lactate sensor as an equivalent circuit to validate the principle of sensor o

85 The equivalent circuit used for fitting the EIS spectra prov

86 The equivalent circuit was verified using a full-wave 3D ele

87 interfacial resistance and capacitance using equivalent circuits, we find that the only parameter tha

88 s were interpreted on the basis of a Randles equivalent circuit where the binding of hydrophobic elec

89 ce in impedance was analyzed using a derived equivalent circuit, which is similar to that of open fin

90 ce in impedance was analyzed using a derived equivalent circuit, which is similar to that of open fin

91 ease gap were modeled with a simple Thevenin equivalent circuit, which satisfactorily predicted the e

92 )NSs-FTO based electrochemical cell fits an equivalent circuit with the circuit elements of solution